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Shackelford, James F. et al “Frontmatter” Materials Science and Engineering Handbook Ed. James F. Shackelford & W. Alexander Boca Raton: CRC Press LLC, 2001
CRC
MATERIALS SCIENCE AND
ENGINEERING HANDBOOK THIRD EDITION
©2001 CRC Press LLC
CRC
MATERIALS SCIENCE AND
ENGINEERING HANDBOOK THIRD EDITION James F. Shackelford Professor of Materials Science and Engineering Division of Materials Science and Engineering and Associate Dean of the College of Engineering University of California, Davis
William Alexander Research Engineer Division of Materials Science and Engineering University of California, Davis
CRC Press Boca Raton London New York Washington, D.C.
©2001 CRC Press LLC
disclaimer Page 1 Wednesday, October 25, 2000 1:50 PM
Library of Congress Cataloging-in-Publication Data CRC materials science and engineering handbook / [edited by] James F. Shackelford, William Alexander.—3rd ed. p. cm. Includes bibliographical references and index. ISBN 0-8493-2696-6 (alk. paper) 1. Materials—Handooks, manuals, etc. I. Shackelford, James F. II. Alexander, William, 1950 Feb. 13TA403.4 .C74 2000 620.1′1—dc21
00-048567
This book contains information obtained from authentic and highly regarded sources. Reprinted material is quoted with permission, and sources are indicated. A wide variety of references are listed. Reasonable efforts have been made to publish reliable data and information, but the author and the publisher cannot assume responsibility for the validity of all materials or for the consequences of their use. Neither this book nor any part may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying, microfilming, and recording, or by any information storage or retrieval system, without prior permission in writing from the publisher. The consent of CRC Press LLC does not extend to copying for general distribution, for promotion, for creating new works, or for resale. Specific permission must be obtained in writing from CRC Press LLC for such copying. Direct all inquiries to CRC Press LLC, 2000 N.W. Corporate Blvd., Boca Raton, Florida 33431. Trademark Notice: Product or corporate names may be trademarks or registered trademarks, and are used only for identification and explanation, without intent to infringe.
© 2001 by CRC Press LLC No claim to original U.S. Government works International Standard Book Number 0-8493-2696-6 Library of Congress Card Number 00-048567 Printed in the United States of America 1 2 3 4 5 6 7 8 9 0 Printed on acid-free paper
©2001 CRC Press LLC
TABLE OF CONTENTS
CHAPTER 1
Structure of Materials Electronic Structure of Selected Elements Available Stable Isotopes of the Elements Periodic Table of the Elements Periodic Table of Elements in Metallic Materials Periodic Table of Elements in Ceramic Materials Periodic Table of Elements in Polymeric Materials Periodic Table of Elements in Semiconducting Materials Periodic Table of Elements in Superconducting Metals Atomic and Ionic Radii of the Elements Bond Length Values Between Elements Periodic Table of Carbon Bond Lengths (Å) Carbon Bond Lengths Carbon Bond Lengths in Polymers Bond Angle Values Between Elements Key to Tables of Crystal Structure of the Elements The Seven Crystal Systems The Fourteen Bravais Lattices Periodic Table of the Body Centered Cubic Elements Periodic Table of the Face Centered Cubic Elements Periodic Table of the Hexagonal Close Packed Elements Periodic Table of the Hexagonal Elements
©2001 CRC Press LLC
Table of Contents Structure of Ceramics Atomic Mass of Selected Elements Solid Density of Selected Elements Density of Iron and Iron Alloys Density of Wrought Stainless Steels Density of Stainless Steels and Heat-Resistant Alloys Density of Aluminum Alloys Density of Copper and Copper Alloys Density of Magnesium and Magnesium Alloys Density of Nickel and Nickel Alloys Density of Lead and Lead Alloys Density of Tin and Tin Alloys Density of Wrought Titanium Alloys Density of Titanium and Titanium alloys Density of Zinc and Zinc Alloys Density of Permanent Magnet Materials Density of Precious Metals Density of Superalloys Density of Selected Ceramics Density of Glasses Specific Gravity of Polymers Density of 55MSI Graphite/6061 Aluminum Composites Density of Graphite Fiber Reinforced Metals Density of Si3N4 Composites CHAPTER 2
Composition of Materials Composition Limits of Tool Steels Composition Limits of Gray Cast Irons Composition Limits of Ductile Irons Composition Ranges for Malleable Irons Composition Ranges for Carbon Steels Composition Ranges for Resulfurized Carbon Steels Composition Ranges for Alloy Steels
©2001 CRC Press LLC CRC Handbook of Materials Science & Engineering
Table of Contents Composition of Stainless Steels Composition of Wrought Coppers and Copper Alloys Classification of Copper and Copper Alloys Composition Ranges for Cast Aluminum Alloys Composition Ranges for Wrought Aluminum Alloys Composition of Tin and Tin Alloys Compositions of ACI Heat-Resistant Casting Alloys Composition of Zinc Die Casting Alloys Compositions of Wrought Superalloys Typical Composition of Glass-Ceramics CHAPTER 3
Phase Diagram Sources Phase Diagram Sources
CHAPTER 4
Thermodynamic and Kinetic Data Bond Strengths in Diatomic Molecules Bond Strengths of Polyatomic Molecules Solubility of Copper and Copper Alloys Heat of Formation of Inorganic Oxides Phase Change Thermodynamic Properties for The Elements Phase Change Thermodynamic Properties of Oxides Melting Points of the Elements Melting Points of Elements and Inorganic Compounds Melting Points Of Ceramics Heat of Fusion For Elements and Inorganic Compounds Heats of Sublimation of Metals and Their Oxides Key to Tables of Thermodynamic Coefficients Thermodynamic Coefficients for Selected Elements Thermodynamic Coefficients for Oxides Entropy of the Elements Vapor Pressure of the Elements at Very Low Pressures Vapor Pressure of the Elements at Moderate Pressures Vapor Pressure of the Elements at High Pressures Vapor Pressure of Elements and Inorganic Compounds
©2001 CRC Press LLC Shackelford & Alexander
Table of Contents Values of The Error Function Diffusion in Metallic Systems Diffusion of Metals into Metals Diffusion in Semiconductors CHAPTER 5
Thermal Properties of Materials Specific Heat of the Elements at 25 ˚C Heat Capacity of Ceramics Specific Heat of Polymers Specific Heat of Fiberglass Reinforced Plastics Thermal Conductivity of Metals (Part 1) Thermal Conductivity of Metals (Part 2) Thermal Conductivity of Metals (Part 3) Thermal Conductivity of Metals (Part 4) Thermal Conductivity of Alloy Cast Irons Thermal Conductivity of Iron and Iron Alloys Thermal Conductivity of Aluminum and aluminum alloys Thermal Conductivity of Copper and Copper Alloys Thermal Conductivity of Magnesium and Magnesium Alloys Thermal Conductivity of Nickel and Nickel Alloys Thermal Conductivity of Lead and Lead Alloys Thermal Conductivity of Tin, Titanium, Zinc and their Alloys Thermal Conductivity of Pure Metals Thermal Conductivity of Ceramics Thermal Conductivity of Glasses Thermal Conductivity of Cryogenic Insulation Thermal Conductivity of Cryogenic Supports Thermal Conductivity of Special Concretes Thermal Conductivity of SiC-Whisker-Reinforced Ceramics Thermal Conductivity of Polymers Thermal Conductivity of Fiberglass Reinforced Plastics Thermal Expansion of Wrought Stainless Steels Thermal Expansion of Wrought Titanium Alloys
©2001 CRC Press LLC CRC Handbook of Materials Science & Engineering
Table of Contents Thermal Expansion of Graphite Magnesium Castings Linear Thermal Expansion of Metals and Alloys Thermal Expansion of Ceramics Thermal Expansion of SiC-Whisker-Reinforced Ceramics Thermal Expansion of Glasses Thermal Expansion of Polymers Thermal Expansion Coefficients of Materials for Integrated Circuits Thermal Expansion of Silicon Carbide SCS–2–Al ASTM B 601 Temper Designation Codes for Copper and Copper Alloys Temper Designation System for Aluminum Alloys Tool Steel Softening After 100 Hours Thermoplastic Polyester Softening with Temperature Heat-Deflection Temperature of Carbon- and Glass-Reinforced Engineering Thermoplastics CHAPTER 6
Mechanical Properties of Materials Tensile Strength of Tool Steels Tensile Strength of Gray Cast Irons Tensile Strength of Gray Cast Iron Bars Tensile Strength of Ductile Irons Tensile Strength of Malleable Iron Castings Tensile Strength of Austenitic Stainless Steels Tensile Strength of Ferritic Stainless Steels Tensile Strength of Precipitation-Hardening Austenitic Stainless Steels Tensile Strength of High–Nitrogen Austenitic Stainless Steels Tensile Strength of Martensitic Stainless Steels Tensile Strength of Wrought Coppers and Copper Alloys Tensile Strength of Aluminum Casting Alloys Tensile Strength of Wrought Aluminum Alloys Tensile Strength of Cobalt-Base Superalloys Tensile Strength of Nickel-Base Superalloys
©2001 CRC Press LLC Shackelford & Alexander
Table of Contents Tensile Strength of Wrought Titanium Alloys at Room Temperature Tensile Strength of Wrought Titanium Alloys at High Temperature Tensile Strength of Refractory Metal Alloys Tensile Strength of Ceramics Tensile Strength of Glass Tensile Strength of Polymers Tensile Strength of Fiberglass Reinforced Plastics Tensile Strength of Carbon- and Glass-Reinforced Engineering Thermoplastics Strength of Graphite Fiber Reinforced Metals Tensile Strength of Graphite/Magnesium Castings Tensile Strength of Graphite/Aluminum Composites Tensile Strength of Graphite/Aluminum Composites Tensile Strength of Silicon Carbide SCS–2–Al Ultimate Tensile Strength of Investment Cast Silicon Carbide SCS–Al Ultimate Tensile Strength of Silicon Carbide–Aluminum Alloy Composites Tensile Strength of SiC-Whisker–Reinforced Aluminum Alloy Ultimate Tensile Strength of Aluminum Alloy Reinforced with SiC Whiskers vs. Temperature Ultimate Tensile Strength of Reinforced Aluminum Alloy vs. Temperature Tensile Strength of Polycrystalline–Alumina–Reinforced Aluminum Alloy Tensile Strength of Boron/Aluminum Composites Compressive Strength of Gray Cast Iron Bars Compressive Strength of Ceramics Compressive Strength of Fiberglass Reinforced Plastic Ultimate Compressive Strength of Investment Cast Silicon Carbide SCS–Al Yield Strength of Tool Steels Yield Strength of Ductile Irons Yield Strength of Malleable Iron Castings Yield Strength of Austenitic Stainless Steels
©2001 CRC Press LLC CRC Handbook of Materials Science & Engineering
Table of Contents Yield Strength of Ferritic Stainless Steels Yield Strength of Martensitic Stainless Steels Yield Strength of Precipitation-Hardening Austenitic Stainless Steels Yield Strength of High–Nitrogen Austenitic Stainless Steels Yield Strength of Wrought Coppers and Copper Alloys Yield Strength of Cast Aluminum Alloys Yield Strength of Wrought Aluminum Alloys Yield Strength of Wrought Titanium Alloys at Room Temperature Yield Strength of Wrought Titanium Alloys at High Temperature Yield Strength of Cobalt-Base Superalloys Yield Strength of Nickel-Base Superalloys Yield Strength of Commercially Pure Tin Yield Strength of Polymers Yield Strength of SiC-Whisker–Reinforced Aluminum Alloy Yield Strength of Reinforced Aluminum Alloy vs. Temperature Yield Strength of Polycrystalline–Alumina–Reinforced Aluminum Alloy Compressive Yield Strength of Polymers Flexural Strength of Polymers Flextural Strength of Fiberglass Reinforced Plastics Shear Strength of Wrought Aluminum Alloys Torsion Shear Strength of Gray Cast Fe Hardness of Gray Cast Irons Hardness of Gray Cast Iron Bars Hardness of Malleable Iron Castings Hardness of Ductile Irons Hardness of Tool Steels Hardness of Austenitic Stainless Steels Hardness of Ferritic Stainless Steels Hardness of Martensitic Stainless Steels Hardness of Precipitation-Hardening Austenitic Stainless Steels Machinability Rating of Wrought Coppers and Copper Alloys Hardness of Wrought Aluminum Alloys Hardness of Wrought Titanium Alloys at Room Temperature
©2001 CRC Press LLC Shackelford & Alexander
Table of Contents Hardness of Ceramics Microhardness of Glass Hardness of Polymers Hardness of Si3N4 and Al2O3 Composites Coefficient of Static Friction for Polymers Abrasion Resistance of Polymers Fatigue Strength of Wrought Aluminum Alloys Reversed Bending Fatigue Limit of Gray Cast Iron Bars Impact Energy of Tool Steels Impact Strength of Wrought Titanium Alloys at Room Temperature Impact Strength of Polymers Impact Strength of Fiberglass Reinforced Plastics Impact Strength of Carbon- and Glass-Reinforced Engineering Thermoplastics Fracture Toughness of Si3N4 and Al2O3 Composites Tensile Modulus of Gray Cast Irons Tension Modulus of Treated Ductile Irons Tensile Modulus of Fiberglass Reinforced Plastics Tensile Modulus of Graphite/Aluminum Composites Tensile Modulus of Investment Cast Silicon Carbide SCS–Al Tensile Modulus of Silicon Carbide SCS–2–Al Young’s Modulus of Ceramics Young’s Modulus of Glass Elastic Modulus of Wrought Stainless Steels Modulus of Elasticity of Wrought Titanium Alloys Modulus of Elasticity in Tension for Polymers Modulus of Elasticity of 55MSI Graphite/6061 Aluminum Composites Modulus of Elasticity of Graphite/Magnesium Castings Modulus of Elasticity of Graphite/Aluminum Composites Modulus of Elasticity of Graphite Fiber Reinforced Metals Modulus of Elasticity of SiC-Whisker–Reinforced Aluminum Alloy
©2001 CRC Press LLC CRC Handbook of Materials Science & Engineering
Table of Contents Modulus of Elasticity of Polycrystalline–Alumina–Reinforced Aluminum Alloy Modulus of Elasticity of Boron/Aluminum Composites Compression Modulus of Treated Ductile Irons Modulus of Elasticity in Compression for Polymers Bulk Modulus of Glass Shear Modulus of Glass Torsional Modulus of Gray Cast Irons Torsion Modulus of Treated Ductile Irons Modulus of Elasticity in Flexure for Polymers Flexural Modulus of Fiberglass Reinforced Plastics Flexural Modulus of Carbon- and Glass-Reinforced Engineering Thermoplastics Modulus of Rupture for Ceramics Rupture Strength of Refractory Metal Alloys Rupture Strength of Superalloys Modulus of Rupture for Si3N4 and Al2O3Composites Poisson's Ratio of Wrought Titanium Alloys Poisson’s Ratio for Ceramics Poisson’s Ratio of Glass Poisson's Ratio of Silicon Carbide SCS–2–Al Compression Poisson’s Ratio of Treated Ductile Irons Torsion Poisson’s Ratio of Treated Ductile Irons Elongation of Tool Steels Elongation of Ductile Irons Elongation of Malleable Iron Castings Elongation of Ferritic Stainless Steels Elongation of Martensitic Stainless Steels Elongation of Precipitation-Hardening Austenitic Stainless Steels Elongation of High–Nitrogen Austenitic Stainless Steels Total Elongation of Cast Aluminum Alloys Elongation of Wrought Coppers and Copper Alloys Elongation of Commercially Pure Tin
©2001 CRC Press LLC Shackelford & Alexander
Table of Contents Elongation of Cobalt-Base Superalloys Elongation of Nickel-Base Superalloys Ductility of Refractory Metal Alloys Elongation of Wrought Titanium Alloys at Room Temperature Elongation of Wrought Titanium Alloys at High Temperature Total Elongation of Polymers Elongation at Yield for Polymers Ultimate Tensile Elongation of Fiberglass Reinforced Plastics Total Strain of Silicon Carbide SCS–2–Al Area Reduction of Tool Steels Reduction in Area of Austenitic Stainless Steels Reduction in Area of Ferritic Stainless Steels Reduction in Area of High–Nitrogen Austenitic Stainless Steels Reduction in Area of Precipitation-Hardening Austenitic Stainless Steels Reduction in Area of Martensitic Stainless Steels Reduction in Area of Commercially Pure Tin Area Reduction of Wrought Titanium Alloys at Room Temperature Area Reduction of Wrought Titanium Alloys at High Temperature Strength Density Ratio of Graphite Fiber Reinforced Metals Modulus Density Ratio of Graphite Fiber Reinforced Metals Viscosity of Glasses Internal Friction of SiO2 Glass Surface Tension of Elements at Melting Surface Tension of Liquid Elements CHAPTER 7
Electrical Properties of Materials Electrical Conductivity of Metals Electrical Resistivity of Metals Electrical Resistivity of Alloy Cast Irons Resistivity of Ceramics Volume Resistivity of Glass Volume Resistivity of Polymers
©2001 CRC Press LLC CRC Handbook of Materials Science & Engineering
Table of Contents Critical Temperature of Superconductive Elements Dissipation Factor for Polymers Dielectric Strength of Polymers Step Dielectric Strength of Polymers Dielectric Constant of Polymers Dielectric Breakdown of Polymers Dielectric Breakdown of Polymers Tangent Loss in Glass Electrical Permittivity of Glass Arc Resistance of Polymers CHAPTER 8
Optical Properties of Materials Transmission Range of Optical Materials Transparency of Polymers Refractive Index of Polymers Dispersion of Optical Materials
CHAPTER 9
Chemical Properties of Materials Water Absorption of Polymers Standard Electromotive Force Potentials Galvanic Series of Metals Galvanic Series of Metals in Sea Water Corrosion Rate of Metals in Acidic Solutions Corrosion Rate of Metals in Neutral and Alkaline Solutions Corrosion Rate of Metals in Air Corrosion Rates of 1020 Steel at 70˚F Corrosion Rates of Grey Cast Iron at 70˚F Corrosion Rates of Ni–Resist Cast Iron at 70˚F Corrosion Rates of 12% Cr Steel at 70˚ Corrosion Rates of 17% Cr Steel at 70˚F Corrosion Rates of 14% Si Iron at 70˚F Corrosion Rates of Stainless Steel 301 at 70˚F Corrosion Rates of Stainless Steel 316 at 70˚F Corrosion Rates of Aluminum at 70˚F
©2001 CRC Press LLC Shackelford & Alexander
Table of Contents Corrosion Resistance of Wrought Coppers and Copper Alloys Corrosion Rates of 70-30 Brass at 70˚F Corrosion Rates of Copper, Sn-Braze, Al-Braze at 70˚F Corrosion Rates of Silicon Bronze at 70˚F Corrosion Rates of Hastelloy at 70˚F Corrosion Rates of Inconel at 70˚F Corrosion Rates of Nickel at 70˚F Corrosion Rates of Monel at 70˚F Corrosion Rates of Lead at 70˚F Corrosion Rates of Titanium at 70˚F Corrosion Rates of ACI Heat–Resistant Castings Alloys in Air Corrosion Rates for ACI Heat–Resistant Castings Alloys in Flue Gas Flammability of Polymers Flammability of Fiberglass Reinforced Plastics CHAPTER 10
Selecting Structural Properties Selecting Atomic Radii of the Elements Selecting Ionic Radii of the Elements Selecting Bond Lengths Between Elements Selecting Bond Angles Between Elements Selecting Density of the Elements
CHAPTER 11
Selecting Thermodynamic and Kinetic Properties Selecting Bond Strengths in Diatomic Molecules Selecting Bond Strengths of Polyatomic Molecules Selecting Heat of Formation of Inorganic Oxides Selecting Specific Heat of Elements Selecting Specific Heat of Polymers Selecting Melting Points of The Elements Selecting Melting Points of Elements and Inorganic Compounds Selecting Melting Points of Ceramics Selecting Heat of Fusion For Elements and Inorganic Compounds Selecting Entropy of the Elements
©2001 CRC Press LLC CRC Handbook of Materials Science & Engineering
Table of Contents Selecting Diffusion Activation Energy in Metallic Systems CHAPTER 12
Selecting Thermal Properties Selecting Thermal Conductivity of Metals Selecting Thermal Conductivity of Metals at Temperature Selecting Thermal Conductivity of Alloy Cast Irons Selecting Thermal Conductivity of Ceramics Selecting Thermal Conductivity of Ceramics at Temperature Selecting Thermal Conductivity of Polymers Selecting Thermal Expansion of Tool Steels Selecting Thermal Expansion of Tool Steels at Temperature Selecting Thermal Expansion of Alloy Cast Irons Selecting Thermal Expansion of Ceramics Selecting Thermal Expansion of Glasses Selecting Thermal Expansion of Polymers Selecting Thermal Expansion Coefficients for Materials used in Integrated Circuits Selecting Thermal Expansion Coefficients for Materials used in Integrated Circuits at Temperature
CHAPTER 13
Selecting Mechanical Properties Selecting Tensile Strength of Tool Steels Selecting Tensile Strength of Gray Cast Irons Selecting Tensile Strength of Ductile Irons Selecting Tensile Strengths of Malleable Iron Castings Selecting Tensile Strengths of Aluminum Casting Alloys Selecting Tensile Strengths of Wrought Aluminum Alloys Selecting Tensile Strengths of Ceramics Selecting Tensile Strengths of Glass Selecting Tensile Strengths of Polymers Selecting Compressive Strengths of Gray Cast Iron Bars Selecting Compressive Strengths of Ceramics Selecting Compressive Strengths of Polymers Selecting Yield Strengths of Tool Steels
©2001 CRC Press LLC Shackelford & Alexander
Table of Contents Selecting Yield Strengths of Ductile Irons Selecting Yield Strengths of Malleable Iron Castings Selecting Yield Strengths of Cast Aluminum Alloys Selecting Yield Strengths of Wrought Aluminum Alloys Selecting Yield Strengths of Polymers Selecting Compressive Yield Strengths of Polymers Selecting Flexural Strengths of Polymers Selecting Shear Strengths of Wrought Aluminum Alloys Selecting Torsional Shear Strengths of Gray Cast Iron Bars Selecting Hardness of Tool Steels Selecting Hardness of Gray Cast Irons Selecting Hardness of Gray Cast Iron Bars Selecting Hardness of Ductile Irons Selecting Hardness of Malleable Iron Castings Selecting Hardness of Wrought Aluminum Alloys Selecting Hardness of Ceramics Selecting Microhardness of Glass Selecting Hardness of Polymers Selecting Coefficients of Static Friction for Polymers Selecting Abrasion Resistance of Polymers Selecting Fatigue Strengths of Wrought Aluminum Alloys Selecting Reversed Bending Fatigue Limits of Gray Cast Iron Bars Selecting Impact Energy of Tool Steels Selecting Impact Strengths of Polymers Selecting Tensile Moduli of Gray Cast Irons Selecting Tensile Moduli of Treated Ductile Irons Selecting Young’s Moduli of Ceramics Selecting Young’s Moduli of Glass Selecting Moduli of Elasticity in Tension for Polymers Selecting Compression Moduli of Treated Ductile Irons Selecting Modulus of Elasticity in Compression for Polymers Selecting Bulk Moduli of Glass
©2001 CRC Press LLC CRC Handbook of Materials Science & Engineering
Table of Contents Selecting Moduli of Elasticity in Flexure of Polymers Selecting Shear Moduli of Glass Selecting Torsional Moduli of Gray Cast Irons Selecting Torsional Moduli of Treated Ductile Irons Selecting Moduli of Rupture for Ceramics Selecting Poisson’s Ratios for Ceramics Selecting Poisson’s Ratios of Glass Selecting Compression Poisson’s Ratios of Treated Ductile Irons Selecting Torsion Poisson’s Ratios of Treated Ductile Irons Selecting Elongation of Tool Steels Selecting Elongation of Ductile Irons Selecting Elongation of Malleable Iron Castings Selecting Total Elongation of Cast Aluminum Alloys Selecting Total Elongation of Polymers Selecting Elongation at Yield of Polymers Selecting Area Reduction of Tool Steels CHAPTER 14
Selecting Electrical Properties Selecting Electrical Resistivity of Alloy Cast Irons Selecting Resistivity of Ceramics Selecting Volume Resistivity of Glass Selecting Volume Resistivity of Polymers Selecting Critical Temperature of Superconductive Elements Selecting Dissipation Factor for Polymers at 60 Hz Selecting Dissipation Factor for Polymers at 1 MHz Selecting Dielectric Strength of Polymers Selecting Dielectric Constants of Polymers at 60 Hz Selecting Dielectric Constants of Polymers at 1 MHz Selecting Tangent Loss in Glass Selecting Tangent Loss in Glass by Temperature Selecting Tangent Loss in Glass by Frequency Selecting Electrical Permittivity of Glass Selecting Electrical Permittivity of Glass by Frequency
©2001 CRC Press LLC Shackelford & Alexander
Table of Contents Selecting Arc Resistance of Polymers CHAPTER 15
Selecting Optical Properties Selecting Transmission Range of Optical Materials Selecting Transparency of Polymers Selecting Refractive Indices of Glasses Selecting Refractive Indices of Polymers
CHAPTER 16
Selecting Chemical Properties Selecting Water Absorption of Polymers Selecting Iron Alloys in 10% Corrosive Medium Selecting Iron Alloys in 100% Corrosive Medium Selecting Nonferrous Metals for use in a 10% Corrosive Medium Selecting Nonferrous Metals for use in a 100% Corrosive Medium Selecting Corrosion Rates of Metals Selecting Corrosion Rates of Metals in Corrosive Environments Selecting Flammability of Polymers
©2001 CRC Press LLC CRC Handbook of Materials Science & Engineering
2.1 Front Matter Page xvii Wednesday, December 31, 1969 17:00
Dedication
To Penelope and Scott Li-Li and Cassie
©2001 CRC Press LLC Shackelford & Alexander
Shackelford, James F. et al “Structure of Materials” Materials Science and Engineering Handbook Ed. James F. Shackelford & W. Alexander Boca Raton: CRC Press LLC, 2001
3.0 Structure Page 1 Wednesday, December 31, 1969 17:00
CHAPTER 1
Structure of Materials
List of Tables
Subatomic Structure Electronic Structure of Selected Elements Available Stable Isotopes of the Elements Atomic Structure Periodic Table of the Elements Periodic Table of Elements in Metallic Materials Periodic Table of Elements in Ceramic Materials Periodic Table of Elements in Polymeric Materials Periodic Table of Elements in Semiconducting Materials Periodic Table of Elements in Superconducting Metals Bond Structure Atomic and Ionic Radii of the Elements Bond Length Values Between Elements Periodic Table of Carbon Bond Lengths (Å) Carbon Bond Lengths Carbon Bond Lengths in Polymers Bond Angle Values Between Elements Crystal Structure Key to Tables of Crystal Structure of the Elements The Seven Crystal Systems
©2001 CRC Press LLC
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3.0 Structure Page 2 Wednesday, December 31, 1969 17:00
Structural Properties List of Tables (Continued)
The Fourteen Bravais Lattices Periodic Table of the Body Centered Cubic Elements Periodic Table of the Face Centered Cubic Elements Periodic Table of the Hexagonal Close Packed Elements Periodic Table of the Hexagonal Elements Structure of Ceramics Density Atomic Mass of Selected Elements Solid Density of Selected Elements Density of Iron and Iron Alloys Density of Wrought Stainless Steels Density of Stainless Steels and Heat-Resistant Alloys Density of Aluminum Alloys Density of Copper and Copper Alloys Density of Magnesium and Magnesium Alloys Density of Nickel and Nickel Alloys Density of Lead and Lead Alloys Density of Tin and Tin Alloys Density of Wrought Titanium Alloys Density of Titanium and Titanium alloys Density of Zinc and Zinc Alloys Density of Permanent Magnet Materials Density of Precious Metals Density of Superalloys Density of Selected Ceramics Density of Glasses Specific Gravity of Polymers Density of 55MSI Graphite/6061 Aluminum Composites Density of Graphite Fiber Reinforced Metals Density of Si3N4 Composites
©2001 CRC Press LLC
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CRC Handbook of Materials Science & Engineering
3.1 Structure Page 3 Wednesday, December 31, 1969 17:00
Structural Properties
Table 1. ELECTRONIC
At. Element No. 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54
Hydrogen Helium Lithium Beryllium Boron Carbon Nitrogen Oxygen Fluorine Neon Sodium Magnesium Aluminum Silicon Phosphorus Sulfur Chlorine Argon Potassium Calcium Scandium Titanium Vanadium Chromium Manganese Iron Cobalt Nickel Copper Zinc Gallium Germanium Arsenic Selenium Bromine Krypton Rubidium Strontium Yttrium Zirconium Niobium Molybdenum Technetium Ruthenium Rhodium Palladium Silver Cadmium Indium Tin Antimony Tellurium Iodine Xenon
STRUCTURE OF SELECTED ELEMENTS
Sym H He Li Be B C N O F N Na Mg Al Si P S Cl Ar K Ca Sc Ti V Cr Mn Fe Co Ni Cu Zn Ga Ge As Se Br Kr Rb Sr Y Zr Nb Mo Tc Ru Rh Pd Ag Cd In Sn Sb Te I Xe
Electronic Configuration 1s 2s 2p 3s 3p 1 2 . 1 . 2 . 2 1 . 2 2 . 2 3 . 2 4 . 2 5 . 2 6 . . . 1 . . . 2 . . . 2 1 . . . 2 2 . . . 2 3 . . . 2 4 . . . 2 5 . . . 2 6 . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3d 4s
1 2 3 5 5 6 7 8 10 10 10 10 10 10 10 10 . . . . . . . . . . . . . . . . . .
1 2 2 2 2 1 2 2 2 2 1 2 2 2 2 2 2 2 . . . . . . . . . . . . . . . . . .
4p 4d
1 2 3 4 5 6 . . . . . . . . . . . . . . . . . .
1 2 4 5 6 7 8 10 10 10 10 10 10 10 10 10
4f
5s
5p 5d
5f
6s
6p 6d 7s
1 2 2 2 1 1 1 1 1 1 2 2 2 2 2 2 2
1 2 3 5 5 6
©2001 CRC Press LLC Shackelford & Alexander
3
3.1 Structure Page 4 Wednesday, December 31, 1969 17:00
Structural Properties
At. Element No.
Sym
Electronic Configuration 1s
55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103
Cesium Barium Lantium Cerium Praseodymium Neodymium Promethium Samarium Europium Gadolinium Terbium Dysprosium Holmium Erbium Thulium Ytterbium Lutetium Hafnium Tantalum Tungsten Rhenium Osmium Iridium Platinum Gold Mercury Thallium Lead Bismuth Polonium Asatine Radon Francium Radium Actinium Thorium Protoactinium Uranium Neptunium Plutonium Americium Curium Berkelium Californium Einsteinium Fermium Mendelevium Nobelium Lawrencium
Ce Ba La Ce Pr Nd Pm Sm Eu Gd Tb Dy Ho Er Tm Yb Lu Hf Ta W Re Os Ir Pt Au Hg Tl Pb Bi Po At Rn Fr Ra Ac Th Pa U Np Pu Am Cm Bk Cf Es Fm Md No Lw
2s
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
2p 3s
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
3p 3d 4s
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4p 4d
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
4f
5s
2 3 4 5 6 7 7 9 10 11 12 13 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 14 . . . . . . . . . . . . . . . . .
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5p 5d
. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .
5f
6p 6d 7s
1 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
1
1
1 2 3 4 5 6 9 9 10 10 10 10 10 10 10 10 . . . . . . . . . . . . . . . . .
6s
2 3 4 6 7 7 9 10 11 12 13 14 14
1 1 2 2 2 2 2 2 2 . . . . . . . . . . . . . . . . .
1 2 3 4 5 6 . . . . . . . . . . . . . . . . .
1 2 1 1 1 1
1
1 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2
©2001 CRC Press LLC
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CRC Handbook of Materials Science & Engineering
3.1 Structure Page 5 Wednesday, December 31, 1969 17:00
Structural Properties
Table 2. AVAILABLE
STABLE ISOTOPES OF THE ELEMENTS (SHEET 1 OF 11) Natural
Element
Mass No.
Abundance (%)
Hydrogen
1
99.985
2
0.015
Helium
3 4
0.00013 ≈100.0
Lithium
6 7
7.42 92.58
Beryllium
9
100.0
Boron
10 11
19.78 80.22
Carbon
12 13
98.89 1.11
Nitrogen
14 15
99.63 0.37
Oxygen
16 17 18
99.76 0.04 0.20
Fluorine
19
100.0
Neon
20 21 22
90.92 0.26 8.82
Sodium
23
100.0
Magnesium
24 25 26
78.70 10.13 11.17
Source: Wang, Y., Ed., Handbook of Radioactive Nuclides, The Chemical Rubber Co., Cleveland, 1969, 25.
©2001 CRC Press LLC Shackelford & Alexander
5
3.1 Structure Page 6 Wednesday, December 31, 1969 17:00
Structural Properties
Table 2. AVAILABLE
STABLE ISOTOPES OF THE ELEMENTS (SHEET 2 OF 11) Natural
Element
Mass No.
Abundance (%)
Aluminum
27
100.0
Silicon
28 29 30
92.21 4.70 3.09
Phosphorus
31
100.0
Sulfur
32 33 34 36
95.0 0.76 4.22 0.014
Chlorine
35 37
75.53 24.47
Argon
36 38 40
0.34 0.06 99.60
Potassium
39 40a 41
93.1
0.01
Calcium
40 42 43 44 46 48
96.97 0.64 0.14 2.06 0.003 0.18
Scandium
45
100.0
6.9
Source: Wang, Y., Ed., Handbook of Radioactive Nuclides, The Chemical Rubber Co., Cleveland, 1969, 25.
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CRC Handbook of Materials Science & Engineering
3.1 Structure Page 7 Wednesday, December 31, 1969 17:00
Structural Properties
Table 2. AVAILABLE
STABLE ISOTOPES OF THE ELEMENTS (SHEET 3 OF 11) Natural Mass No.
Abundance (%)
Titanium
46 47 48 49 50
7.93 7.28 73.94 5.51 5.34
Vanadium
50 51
0.24 99.76
Chromium
50 52 53 54
4.31 83.76 9.55 2.38
Manganese
55
100.0
Iron
54 56 57 58
5.82 91.66 2.19 0.33
Cobalt
59
100.0
Nickel
58 60 61 62 64
67.84 26.23 1.19 3.66 1.08
Copper
63 65
69.09 30.91
Element
Source: Wang, Y., Ed., Handbook of Radioactive Nuclides, The Chemical Rubber Co., Cleveland, 1969, 25.
©2001 CRC Press LLC Shackelford & Alexander
7
3.1 Structure Page 8 Wednesday, December 31, 1969 17:00
Structural Properties
Table 2. AVAILABLE
STABLE ISOTOPES OF THE ELEMENTS (SHEET 4 OF 11) Natural Mass No.
Abundance (%)
Zinc
64 66 67 68 70
48.89 27.81 4.11 18.57 0.62
Gallium
69 71
60.4 39.6
Germanium
70 72 73 74 76
20.52 27.43 7.76 36.54 7.76
Arsenic
75
100.0
Selenium
74 76 77 78 80 82
0.87 9.02 7.58 23.52 49.82 9.19
Bromine
79 81
50.54 49.46
Krypton
78 80 82 83 84 86
0.35 2.27 11.56 11.55 56.90 17.37
Rubidium
85 87
72.15 27.85
Element
Source: Wang, Y., Ed., Handbook of Radioactive Nuclides, The Chemical Rubber Co., Cleveland, 1969, 25.
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CRC Handbook of Materials Science & Engineering
3.1 Structure Page 9 Wednesday, December 31, 1969 17:00
Structural Properties
Table 2. AVAILABLE
STABLE ISOTOPES OF THE ELEMENTS (SHEET 5 OF 11) Natural Mass No.
Abundance (%)
Strontium
84 86 87 88
0.56 9.86 7.02 82.56
Yttrium
89
100.0
Zirconium
90 91 92 94 96
51.46 11.23 17.11 17.40 2.80
Niobium
93
100.0
Molybdenum
92 94 95 96 97 98 100
15.84 9.04 15.72 16.53 9.46 23.78 9.63
Ruthenium
96 98 99 100 101 102 104
5.51 1.87 12.72 12.62 17.07 31.61 18.60
Rhodium
103
100.0
Element
Source: Wang, Y., Ed., Handbook of Radioactive Nuclides, The Chemical Rubber Co., Cleveland, 1969, 25.
©2001 CRC Press LLC Shackelford & Alexander
9
3.1 Structure Page 10 Wednesday, December 31, 1969 17:00
Structural Properties
Table 2. AVAILABLE
STABLE ISOTOPES OF THE ELEMENTS (SHEET 6 OF 11) Natural Mass No.
Abundance (%)
Palladium
102 104 105 106 108 110
0.96 10.97 22.23 27.33 26.71 11.81
Silver
107 109
51.82 48.18
Cadmium
106 108 110 111 112 113 114 116
1.22 0.88 12.39 12.75 24.07 12.26 28.86 7.58
Indium
113 115
4.28 95.72
Tin
112 114 115 116 117 118 119 120 122 124
0.96 0.66 0.35 14.30 7.61 24.03 8.58 32.85 4.72 5.94
Antimony
121 123
57.25 42.75
Element
Source: Wang, Y., Ed., Handbook of Radioactive Nuclides, The Chemical Rubber Co., Cleveland, 1969, 25.
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CRC Handbook of Materials Science & Engineering
3.1 Structure Page 11 Wednesday, December 31, 1969 17:00
Structural Properties
Table 2. AVAILABLE
STABLE ISOTOPES OF THE ELEMENTS (SHEET 7 OF 11) Natural Mass No.
Abundance (%)
Tellurium
120 122 123 124 125 126 128 130
0.09 2.46 0.87 4.61 6.99 18.71 31.79 34.48
Iodine
127
100.0
Xenon
124 126 128 129 130 131 132 134 136
0.096 0.090 1.92 26.44 4.08 21.18 26.89 10.44 8.87
Cesium
133
100.0
Barium
130 132 134 135 136 137 138
0.101 0.097 2.42 6.59 7.81 11.30 71.66
Lanthanum
138 139
0.09 99.91
Element
Source: Wang, Y., Ed., Handbook of Radioactive Nuclides, The Chemical Rubber Co., Cleveland, 1969, 25.
©2001 CRC Press LLC Shackelford & Alexander
11
3.1 Structure Page 12 Wednesday, December 31, 1969 17:00
Structural Properties
Table 2. AVAILABLE
STABLE ISOTOPES OF THE ELEMENTS (SHEET 8 OF 11) Natural Mass No.
Abundance (%)
136 138 140 142d
0.193 0.250 88.48
11.07
141
100.0
Neodymium
142 143 144 146 148 150
27.11 12.17 23.85 17.22 5.73 5.62
Samarium
144 147e 148f 149g 150 152 154
Element Cerium
Praseodymium
3.09
14.97 11.24 13.83 7.44 26.72 22.71
Europium
151 153
47.82 52.18
Gadolinium
152h 154 155 156 157 158 160
0.20 2.15 14.73 20.47 15.68 24.87 21.90
159
100.0
Terbium
Source: Wang, Y., Ed., Handbook of Radioactive Nuclides, The Chemical Rubber Co., Cleveland, 1969, 25.
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CRC Handbook of Materials Science & Engineering
3.1 Structure Page 13 Wednesday, December 31, 1969 17:00
Structural Properties
Table 2. AVAILABLE
STABLE ISOTOPES OF THE ELEMENTS (SHEET 9 OF 11) Natural Mass No.
Abundance (%)
156i 158 160 161 162 163 164
0.052
Holmium
165 186
100.0 28.41
Erbium
162 164 166 167 168 170 186
0.136 1.56 33.41 22.94 27.07 14.88 1.59
Thulium
169 189
100.0 16.1
Ytterbium
168 170 171 172 173 174 176
0.135 3.03 14.31 21.82 16.13 31.84 12.73
Lutetium
175 176j
97.40
Element
Dysprosium
0.090 2.29 18.88 25.53 24.97 28.18
2.60
Source: Wang, Y., Ed., Handbook of Radioactive Nuclides, The Chemical Rubber Co., Cleveland, 1969, 25.
©2001 CRC Press LLC Shackelford & Alexander
13
3.1 Structure Page 14 Wednesday, December 31, 1969 17:00
Structural Properties
Table 2. AVAILABLE
STABLE ISOTOPES OF THE ELEMENTS (SHEET 10 OF 11) Natural Mass No.
Abundance (%)
174k 176 177 178 179 180
0.18 5.20 18.50 27.14 13.75 35.24
Tantalum
180 181
0.012 99.988
Tungsten
180 182 183 184
0.14 26.41 14.40 30.64
Rhenium
185 187
37.07 62.93
Osmium
184 187 188 190 192
0.018 1.64 13.3 26.4 41.0
Iridium
191 193
37.3 62.7
Platinum
190m 192 194 195 196 198
0.013
197
100.0
Element
Haffiium
Gold
0.78 32.9 33.8 25.3 7.2
Source: Wang, Y., Ed., Handbook of Radioactive Nuclides, The Chemical Rubber Co., Cleveland, 1969, 25.
©2001 CRC Press LLC
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CRC Handbook of Materials Science & Engineering
3.1 Structure Page 15 Wednesday, December 31, 1969 17:00
Structural Properties
Table 2. AVAILABLE
STABLE ISOTOPES OF THE ELEMENTS (SHEET 11 OF 11) Natural Mass No.
Abundance (%)
Mercury
196 198 199 200 201 202 204
0.146 10.02 16.84 23.13 13.22 29.80 6.85
Thallium
203 205
29.50 70.50
Lead
204 206 207 208
1.48 23.6 22.6 52.3
Bismuth
209
100.0
Thorium
232n†
100.0
Uranium
234o† 235p† 238q†
0.0006 0.72 99.27
Element
Source: Wang, Y., Ed., Handbook of Radioactive Nuclides, The Chemical Rubber Co., Cleveland, 1969, 25.
a b c d e f g h
i
half-life = 1.3 x 109 y. half-life > 1015 y half-life = 5 x 1014 y half-life = 5 x 1014 y half-life = 1.06 x 1011 y half-life = 1.2 x 1013 y half-life = 1.2 x 1014 y half-life = 1.1 x 1014 y half-life = 2 x 1014 y
j
half-life = 2.2 x 1010 y k half-life = 4.3 x 1015 y l half-life = 4 x 1010 y m half-life = 6 x 1011 y n half-life = 1.4 x 1010 y o half-life = 2.5 x 105 y p half-life = 7.1 x 108 y q half-life = 4.5 x 109 y † naturally occurring.
©2001 CRC Press LLC Shackelford & Alexander
15
3.2 Structure L Page 16 Wednesday, December 31, 1969 17:00
1 IA
2
3
4
5
Table 3. PERIODIC
TABLE OF THE ELEMENTS
6
9
7
8
10
11
12
13
14
15
16
17
18 VIIA
1 H
IIA
IIIA
IVA
VA
VIA
VIIA
2 He
3 Li
4 Be
5 B
6 C
7 N
8 O
9 F
10 Ne
11 Na
12 Mg
IIIB
IVB
VB
VIB
VIIB
-----
VIII
-----
IB
IIB
13 Al
14 Si
15 P
16 S
17 Cl
18 Ar
19 K
20 Ca
21 Sc
22 Ti
23 V
24 Cr
25 Mn
26 Fe
27 Co
28 Ni
29 Cu
30 Zn
31 Ga
32 Ge
33 As
34 Se
35 Br
36 Kr
37 Rb
38 Sr
39 Y
40 Zr
41 Nb
42 Mo
43 Tc
44 Ru
45 Rh
46 Pd
47 Ag
48 Cd
49 In
50 Sn
51 Sb
52 Te
53 I
54 Xe
55 Cs
56 Ba
72 Hf
73 Ta
74 W
75 Re
76 Os
77 Ir
78 Pt
79 Au
80 Hg
81 Tl
82 Pb
83 Bi
84 Po
85 At
86 Rn
87 Fr
88 Ra
57 La
58 Ce
59 Pr
60 Nd
61 Pm
62 Sm
63 Eu
64 Gd
65 Tb
66 Dy
67 Ho
68 Er
69 Tm
70 Yb
71 Lu
89 Ac
90 Th
91 Pa
92 U
93 Np
94 Pu
95 Am
96 Cm
97 Bk
98 Cf
99 Es
100 Fm
101 Md
102 No
103 Lw
©2001 CRC Press LLC
3.2 Structure L Page 17 Wednesday, December 31, 1969 17:00
Table 4. PERIODIC 1 IA
2
3
4
5
6
TABLE OF ELEMENTS IN METALLIC MATERIALS 7
8
9
10
11
12
13
14
15
16
17
IIA
IIIA
IVA
VA
VIA
VIIA
3 Li
4 Be
5 B
11 Na
12 Mg
IIIB
IVB
VB
VIB
VIIB
-----
VIII
-----
IB
IIB
13 Al
19 K
20 Ca
21 Sc
22 Ti
23 V
24 Cr
25 Mn
26 Fe
27 Co
28 Ni
29 Cu
30 Zn
31 Ga
37 Rb
38 Sr
39 Y
40 Zr
41 Nb
42 Mo
43 Tc
44 Ru
45 Rh
46 Pd
47 Ag
48 Cd
49 In
50 Sn
51 Sb
55 Cs
56 Ba
72 Hf
73 Ta
74 W
75 Re
76 Os
77 Ir
78 Pt
79 Au
80 Hg
81 Tl
82 Pb
83 Bi
87 Fr
88 Ra
57 La
58 Ce
59 Pr
60 Nd
61 Pm
62 Sm
63 Eu
64 Gd
65 Tb
66 Dy
67 Ho
68 Er
69 Tm
70 Yb
71 Lu
89 Ac
90 Th
91 Pa
92 U
93 Np
94 Pu
95 Am
96 Cm
97 Bk
98 Cf
99 Es
100 Fm
101 Md
102 No
103 Lw
©2001 CRC Press LLC
18 VIIA
3.2 Structure L Page 18 Wednesday, December 31, 1969 17:00
Table 5. PERIODIC 1 IA
2
3
4
5
6
TABLE OF ELEMENTS IN CERAMIC MATERIALS
7
8
9
10
11
12
13
14
15
16
17
IIA
IIIA
IVA
VA
VIA
VIIA
3 Li
4 Be
5 B
6 C
7 N
8 O
11 Na
12 Mg
IIIB
IVB
VB
VIB
VIIB
-----
VIII
-----
IB
IIB
13 Al
14 Si
15 P
16 S
19 K
20 Ca
21 Sc
22 Ti
23 V
24 Cr
25 Mn
26 Fe
27 Co
28 Ni
29 Cu
30 Zn
31 Ga
32 Ge
37 Rb
38 Sr
39 Y
40 Zr
41 Nb
42 Mo
43 Tc
44 Ru
45 Rh
46 Pd
47 Ag
48 Cd
49 In
50 Sn
51 Sb
55 Cs
56 Ba
72 Hf
73 Ta
74 W
75 Re
76 Os
77 Ir
78 Pt
79 Au
80 Hg
81 Tl
82 Pb
83 Bi
87 Fr
88 Ra
57 La
58 Ce
59 Pr
60 Nd
61 Pm
62 Sm
63 Eu
64 Gd
65 Tb
66 Dy
67 Ho
68 Er
69 Tm
70 Yb
71 Lu
89 Ac
90 Th
91 Pa
92 U
93 Np
94 Pu
95 Am
96 Cm
97 Bk
98 Cf
99 Es
100 Fm
101 Md
102 No
103 Lw
©2001 CRC Press LLC
18 VIIA
3.2 Structure L Page 19 Wednesday, December 31, 1969 17:00
1 IA 1 H
2
3
Table 6. PERIODIC
TABLE OF ELEMENTS IN POLYMERIC MATERIALS
4
7
5
6
8
9
10
11
12
IIA
IIIB
©2001 CRC Press LLC
IVB
VB
VIB
VIIB
-----
VIII
-----
IB
IIB
13
14
15
16
17
IIIA
IVA
VA
VIA
VIIA
6 C
7 N
8 O
9 F
14 Si
18 VIIA
3.2 Structure L Page 20 Wednesday, December 31, 1969 17:00
Table 7. PERIODIC 1 IA
2
3
4
5
6
TABLE OF ELEMENTS IN SEMICONDUCTING MATERIALS 7
8
9
10
11
12
IIA
13
14
15
16
17
IIIA
IVA
VA
VIA
VIIA
8 O IIIB
IVB
VB
VIB
VIIB
-----
VIII
-----
IB
IIB
13 Al
14 Si
15 P
16 S
30 Zn
31 Ga
32 Ge
33 As
34 Se
48 Cd
49 In
50 Sn
51 Sb
52 Te
80 Hg
©2001 CRC Press LLC
18 VIIA
3.2 Structure L Page 21 Wednesday, December 31, 1969 17:00
Table 8. PERIODIC 1 IA
2
3
4
5
6
TABLE OF ELEMENTS IN SUPERCONDUCTING METALS 7
8
9
10
11
12
IIA
13
14
15
16
17
IIIA
IVA
VA
VIA
VIIA
50 Sn
51 Sb
4 Be IIIB
IVB
VB
22 Ti
23 V
40 Zr
41 Nb
42 Mo
43 Tc
44 Ru
73 Ta
74 W
75 Re
76 Os
57 La 90 Th
©2001 CRC Press LLC
91 Pa
VIB
VIIB
-----
VIII
77 Ir
-----
IB
IIB
13 Al
30 Zn
31 Ga
48 Cd
49 In
80 Hg
82 Pb
18 VIIA
3.3 Structure Page 22 Wednesday, December 31, 1969 17:00
Structural Properties
Table 9. ATOMIC AND IONIC RADII OF THE (SHEET 1 OF 5)
ELEMENTS
Atomic Number
Symbol
Atomic Radius (nm)
Ion
Ionic Radius (nm)
1 2 3 4
H He Li Be
0.046 – 0.152 0.114
H– – Li+ Be2+
0.154 – 0.078 0.054
5 6 7 8
B C N O
0.097 0.077 0.071 0.060
B3+ C4+ N5+ 02–
0.02 1770 789
Source: data from: Lynch, Charles T., Ed., CRC Handbook of Materials Science, Vol. 1, CRC Press, Boca Raton, 1974, 348.
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6.3 Thermodynamics Page 238 Wednesday, December 31, 1969 17:00
Thermodynamic and Kinetic Data
Table 72. MELTING POINTS OF (SHEET 10 OF 11) Compound
CERAMICS
(K)
UC UCl4
2863 843
UF4 UI4
1233
UN UO2
3123 3151 1970
779
USi2 US2
>1375
VB2 VC VCl4
2373 3600 245
VF3
>1075
FI2 VN V2O5
1048 2593 947
VSi2
2023
V2S3
>875 3133 2900 548
WB WC WCl6 WO3 WSi2 WS2
1744
ZnBr2
667
ZnCl2 ZnF2 ZnI2 ZnO
2320 1523
548 1145 719 2248
Source: data from: Lynch, Charles T., Ed., CRC Handbook of Materials Science, Vol. 1, CRC Press, Boca Raton, 1974, 348.
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6.3 Thermodynamics Page 239 Wednesday, December 31, 1969 17:00
Thermodynamic and Kinetic Data
Table 72. MELTING POINTS OF (SHEET 11 OF 11) Compound ZnSO4 ZrB2 ZrBr2 ZrC ZrCl2 ZrF4 ZrI4 ZrN ZrO2 Zr(SO4)2 ZrS2
CERAMICS
(K)
873 3313 >625 3533 623 873 772 3250 3123 683 1823
Source: data from: Lynch, Charles T., Ed., CRC Handbook of Materials Science, Vol. 1, CRC Press, Boca Raton, 1974, 348.
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6.3 Thermodynamics Page 240 Wednesday, December 31, 1969 17:00
Thermodynamic and Kinetic Data
Table 73. HEAT OF
FUSION FOR ELEMENTS AND INORGANIC COMPOUNDS (SHEET 1 OF 16) Heat of fusion
Compound
Formula
Melting point ˚C
Actinium227 Aluminum Aluminum bromide
Ac
1050±50
(11.0)
Al
658.5
94.5
2550
Al2Br6
Aluminum chloride
Al2Cl6
87.4 192.4
10.1 63.6
5420 19600
Aluminum iodide
Al2I6
Aluminum oxide Antimony Antimony pentachloride
Al2O3 Sb SbCl5
190.9 2045.0
9.8 (256.0)
7960 (26000)
630
39.1
4770
4.0
8.0
2400
Antimony tribromide Antimony trichloride Antimony trioxide
SbBr3 SbCl3 Sb4O6
Antimony trisulfide
Sb4S6
96.8 73.3 655.0 546.0
9.7 13.3 (46.3) 33.0
3510 3030 (26990) 11200
Argon Arsenic Arsenic pentafluoride Arsenic tribromide
Ar As AsF5 AsBr3
190.2 816.8
7.25 (22.0)
290 (6620)
80.8 30.0
16.5 8.9
2800 2810
Arsenic trichloride Arsenic trifluoride Arsenic trioxide Barium
AsCl3 AsF3
–16.0 –6.0 312.8
13.3 18.9 22.2
2420 2486 8000
725
13.3
1830
As4O6 Ba
cal/g
cal/g mole
(3400)
For heat of fusion in J/kg, multiply values in cal/g by 4184. For heat of fusion in J/mol, multiply values in cal/g-mol (=cal/mol) by 4.184. For melting point in K, add 273.15 to values in ˚C. Values in parentheses are of uncertain reliability. Source: data from Weast, R C., Ed., Handbook of Chemistry and Physics, 55th ed., CRC Press, Cleveland, (1974); and Bolz, R. E. and Tuve, G. L., Eds., Handbook of Tables for Applied Engineering Science, 2nd ed., CRC Press, Cleveland, (1973)
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6.3 Thermodynamics Page 241 Wednesday, December 31, 1969 17:00
Thermodynamic and Kinetic Data
Table 73. HEAT OF
FUSION FOR ELEMENTS AND INORGANIC COMPOUNDS (SHEET 2 OF 16) Heat of fusion
Compound
Formula
Melting point ˚C
Barium bromide Barium chloride Barium fluoride Barium iodide
BaBr2 BaCl2 BaF2 BaI2
846.8 959.8 1286.8 710.8
21.9 25.9 17.1 (17.3)
6000 5370 3000 (6800)
Barium nitrate Barium oxide Barium phosphate Barium sulfate
Ba(NO3)2 BaO Ba3(PO4)2 BaSO4
(5900)
Beryllium Beryllium bromide Beryllium chloride Beryllium oxide
Be BeBr2 BeCl2 BeO
Bismuth Bismuth trichloride Bismuth trifluoride Bismuth trioxide
Bi BiCl3 BiF3
Boron Boron tribromide Boron trichloride Boron trifluoride
cal/g
cal/g mole
594.8
(22.6)
1922.8
93.2
13800
1727 1350
30.9 41.6
18600 9700
1278
260.0
–
487.8
(26.6)
(4500)
404.8 2550.0
(30) 679.7
(3000) 17000
271
12.0
2505
Bi2O3
223.8 726.0 815.8
8.2 (23.3) 14.6
2600 (6200) 6800
B BBr3 BCl3 BF3
2300
(490)
(5300)
–48.8 –107.8 –128.0
(2.9) (4.3) 7.0
(700) (500) 480
For heat of fusion in J/kg, multiply values in cal/g by 4184. For heat of fusion in J/mol, multiply values in cal/g-mol (=cal/mol) by 4.184. For melting point in K, add 273.15 to values in ˚C. Values in parentheses are of uncertain reliability. Source: data from Weast, R C., Ed., Handbook of Chemistry and Physics, 55th ed., CRC Press, Cleveland, (1974); and Bolz, R. E. and Tuve, G. L., Eds., Handbook of Tables for Applied Engineering Science, 2nd ed., CRC Press, Cleveland, (1973)
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Thermodynamic and Kinetic Data
Table 73. HEAT OF
FUSION FOR ELEMENTS AND INORGANIC COMPOUNDS (SHEET 3 OF 16) Heat of fusion
Melting point ˚C
cal/g
cal/g mole
Compound
Formula
Boron trioxide Bromine Bromine pentafluoride Cadmium
B2O3 Br2 BrF5 Cd
448.8 –7.2 –61.4
78.9 16.1 7.07
5500 2580 1355
320.8
12.9
1460
Cadmium bromide Cadmium chloride Cadmium fluoride Cadmium iodide
CdBr2 CdCl2 CdF2 CdI2
567.8 567.8 1110 386.8
(18.4) 28.8 (35.9) 10.0
(5000) 5300 (5400) 3660
Cadmium sulfate Calcium Calcium bromide Calcium carbonate
CdSO4 Ca CaBr2 CaCO3
1000
22.9
4790
851
55.7
2230
729.8 1282
20.9 (126)
4180 (12700)
Calcium chloride Calcium fluoride Calcium metasilicate Calcium nitrate
CaCl2 CaF2 CaSiO3 Ca(NO3)2
782 1382 1512 560.8
55 52.5 115.4 31.2
6100 4100 13400 5120
Calcium oxide Calcium sulfate Carbon dioxide Carbon monoxide
CaO CaSO4 CO2 CO
2707
(218.1)
(12240)
1297 –57.6
49.2 43.2
6700 1900
–205
7.13
199.7
For heat of fusion in J/kg, multiply values in cal/g by 4184. For heat of fusion in J/mol, multiply values in cal/g-mol (=cal/mol) by 4.184. For melting point in K, add 273.15 to values in ˚C. Values in parentheses are of uncertain reliability. Source: data from Weast, R C., Ed., Handbook of Chemistry and Physics, 55th ed., CRC Press, Cleveland, (1974); and Bolz, R. E. and Tuve, G. L., Eds., Handbook of Tables for Applied Engineering Science, 2nd ed., CRC Press, Cleveland, (1973)
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6.3 Thermodynamics Page 243 Wednesday, December 31, 1969 17:00
Thermodynamic and Kinetic Data
Table 73. HEAT OF
FUSION FOR ELEMENTS AND INORGANIC COMPOUNDS (SHEET 4 OF 16)
Compound
Formula
Cyanogen Cyanogen chloride Cerium Cesium
C2N2 CNCl Ce Cs
Cesium chloride Cesium nitrate Chlorine Chromium
CsCl CsNO3 Cl2 Cr
Chromium (II) chloride Chromium (III) sequioxide Chromium trioxide Cobalt
CrCl2 Cr2O3 CrO3 Co
Cobalt (II) chloride Copper Copper (II) chloride Copper (I) chloride
CoCl2 Cu CuCl2 CuCl
Copper(l) cyanide Copper (I) iodide Copper (II) oxide Copper (I) oxide
Cu2(CN)2 CuI CuO Cu2O
Heat of fusion
Melting point ˚C
cal/g
cal/g mole
–27.2
39.6
2060
–5.2 775 28.3
36.4 27.2 3.7
2240 2120 500
38.5
21.4
3600
406.8 –103±5
16.6 22.8
3250 1531
1890
62.1
3660
814 2279 197
65.9 27.6 37.7
7700 4200 3770
1490
62.1
3640
7390
727
56.9
1083
49.0
3110
430
24.7
4890
429
26.4
2620
473
(30.1)
(5400)
587 1446
(13.6) 35.4
(2600) 2820
1230
(93.6)
(l3400)
For heat of fusion in J/kg, multiply values in cal/g by 4184. For heat of fusion in J/mol, multiply values in cal/g-mol (=cal/mol) by 4.184. For melting point in K, add 273.15 to values in ˚C. Values in parentheses are of uncertain reliability. Source: data from Weast, R C., Ed., Handbook of Chemistry and Physics, 55th ed., CRC Press, Cleveland, (1974); and Bolz, R. E. and Tuve, G. L., Eds., Handbook of Tables for Applied Engineering Science, 2nd ed., CRC Press, Cleveland, (1973)
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Thermodynamic and Kinetic Data
Table 73. HEAT OF
FUSION FOR ELEMENTS AND INORGANIC COMPOUNDS (SHEET 5 OF 16) Heat of fusion
Melting point ˚C
cal/g
cal/g mole
Compound
Formula
Copper (I) sulfide Dysprosium Erbium Europium
Cu2S Dy Er Eu
1129
62.3
5500
1407 1496 826
25.2 24.5 16.4
4100 4100 2500
Europium trichloride Fluorine Gadolinium Gallium
EuCl3 F2 Gd Ga
622 –219.6
(20.9) 6.4
(8000) 244.0
1312 29
23.8 19.1
3700 1336
Germanium Gold Hafnium Holmium
Ge Au Hf Ho
959 1063 2214 1461
(114.3) (15.3) (34.1) 24.8
(8300) 3030 (6000) 4100
Hydrogen Hydrogen bromide Hydrogen chloride Hydrogen fluoride
H2 HBr HCl HF
–259.25
13.8
28
–86.96 –114.3 83.11
7.1 13.0 54.7
575.1 476.0 1094
Hydrogen iodide Hydrogen nitrate
HI HNO3
–50.91
5.4
686.3
Hydrogen oxide (water)
H2O
Deuterium oxide
D2O
–47.2 0 3.78
9.5 79.72 75.8
601 1436 1516
For heat of fusion in J/kg, multiply values in cal/g by 4184. For heat of fusion in J/mol, multiply values in cal/g-mol (=cal/mol) by 4.184. For melting point in K, add 273.15 to values in ˚C. Values in parentheses are of uncertain reliability. Source: data from Weast, R C., Ed., Handbook of Chemistry and Physics, 55th ed., CRC Press, Cleveland, (1974); and Bolz, R. E. and Tuve, G. L., Eds., Handbook of Tables for Applied Engineering Science, 2nd ed., CRC Press, Cleveland, (1973)
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6.3 Thermodynamics Page 245 Wednesday, December 31, 1969 17:00
Thermodynamic and Kinetic Data
Table 73. HEAT OF
FUSION FOR ELEMENTS AND INORGANIC COMPOUNDS (SHEET 6 OF 16)
Compound
Formula
Hydrogen peroxide
H2O2
Hydrogen selenate
H2SeO4
Hydrogen sulfate
H2SO4
Hydrogen sulfide
H2S
Hydrogen sulfide, di–
H2S2
Hydrogen telluride Indium lodine
H2Te In I2
lodine chloride (α) lodine chloride (β) Iron Iron carbide Iron (III) chloride Iron (II) chloride Iron (II) oxide Iron oxide Iron pentacarbonyl Iron (II) sulfide Lanthanum Lead
Heat of fusion
Melting point ˚C
cal/g
cal/g mole
–0.7 57.8 10.4 –85.6
8.58 23.8 24.0 16.8
2920 3450 2360 5683
–89.7 –49.0
27.3 12.9
1805 1670
156.3
6.8
781
112.9
14.3
3650
ICl ICl
17.1 13.8
16.4 13.3
2660 2270
Fe Fe3C
1530.0
63.7
3560
1226.8
68.6
12330
Fe2Cl6 FeCl2 FeO Fe3O4
303.8 677
63.2 61.5
20500 7800
1380
(107.2)
(7700)
1596
142.5
33000
Fe(CO)5 FeS La Pb
–21.2
16.5
3250
1195 920 327.3
56.9 17.4 5.9
5000 2400 1224
For heat of fusion in J/kg, multiply values in cal/g by 4184. For heat of fusion in J/mol, multiply values in cal/g-mol (=cal/mol) by 4.184. For melting point in K, add 273.15 to values in ˚C. Values in parentheses are of uncertain reliability. Source: data from Weast, R C., Ed., Handbook of Chemistry and Physics, 55th ed., CRC Press, Cleveland, (1974); and Bolz, R. E. and Tuve, G. L., Eds., Handbook of Tables for Applied Engineering Science, 2nd ed., CRC Press, Cleveland, (1973)
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Thermodynamic and Kinetic Data
Table 73. HEAT OF
FUSION FOR ELEMENTS AND INORGANIC COMPOUNDS (SHEET 7 OF 16) Heat of fusion
Compound
Formula
Melting point ˚C
Leadbromide Lead chloride Lead fluoride Lead iodide
PbBr2 PbCl2 PbF2 PbI2
487.8 497 8 823 412
11 7 20.3 7.6 17.9
4290 5650 1860 5970
Lead molybdate Lead oxide Lead sulfate Lead sulfide
PbMoO4 PbO PbSO4 PbS
1065
70.8
(25800)
890
12.6
2820
1087
31.6
9600
1114
17.3
4150
Lithium Lithium bromide Lithium chloride Lithium fluoride
Li LiBr LiCl LiF
178.8 552 614 896
158.5 33 4 75.5 (91.1)
1100 2900 3200 (2360)
Lithium hydroxide Lithium iodide Lithium metasilicate
LiOH LiI Li2SiO3
462 440
103.3 (10.6)
2480 (1420)
Lithium molybdate
Li2MoO4
1177 705
80.2 24.1
7210 4200
Lithium nitrate Lithium orthosilicate
LiNO3 Li4SiO4
Lithium sulfate
Li2SO4
Lithium tungstate
Li2WO4
250 1249 857 742
87.8 60.5 27.6 (25.6)
6060 7430 3040 (6700)
cal/g
cal/g mole
For heat of fusion in J/kg, multiply values in cal/g by 4184. For heat of fusion in J/mol, multiply values in cal/g-mol (=cal/mol) by 4.184. For melting point in K, add 273.15 to values in ˚C. Values in parentheses are of uncertain reliability. Source: data from Weast, R C., Ed., Handbook of Chemistry and Physics, 55th ed., CRC Press, Cleveland, (1974); and Bolz, R. E. and Tuve, G. L., Eds., Handbook of Tables for Applied Engineering Science, 2nd ed., CRC Press, Cleveland, (1973)
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6.3 Thermodynamics Page 247 Wednesday, December 31, 1969 17:00
Thermodynamic and Kinetic Data
Table 73. HEAT OF
FUSION FOR ELEMENTS AND INORGANIC COMPOUNDS (SHEET 8 OF 16) Heat of fusion
Melting point ˚C
cal/g
cal/g mole
Compound
Formula
Lutetium Magnesium Magnesium bromide Magnesium chloride
Lu Mg MgBr2 MgCl2
1651 650
26.3 88.9
4600 2160
711 712
45.0 82.9
8300 8100
Magnesium fluoride Magnesium oxide Magnesium silicate Magnesium sulfate
MgF2 MgO MgSiO3 MgSO4
1221
94.7
5900
2642
459.0
18500
1524 1327
146.4 28.9
14700 3500
Manganese Manganese dichloride Manganese metasilicate Manganese (II) oxide
Mn MnCl2 MnSiO3 MnO
1220
62.7
3450
650 1274
58.4 (62.6)
7340 (8200)
1784
183.3
13000
Manganese oxide Mercury Mercury bromide Mercury chloride
Mn3O4 Hg HgBr2 HgCl2
1590
(170.4)
(39000)
–39
2.7
557.2
241 276.8
10.9 15.3
3960 4150
Mercury iodide Mercury sulfate Molybdenum Molybdenum dichloride
HgI2 HgSO4 Mo MoCl2
250 850
9.9 (4.8)
4500 (1440)
2622
(68.4)
(6600)
726.8
3.58
6000
For heat of fusion in J/kg, multiply values in cal/g by 4184. For heat of fusion in J/mol, multiply values in cal/g-mol (=cal/mol) by 4.184. For melting point in K, add 273.15 to values in ˚C. Values in parentheses are of uncertain reliability. Source: data from Weast, R C., Ed., Handbook of Chemistry and Physics, 55th ed., CRC Press, Cleveland, (1974); and Bolz, R. E. and Tuve, G. L., Eds., Handbook of Tables for Applied Engineering Science, 2nd ed., CRC Press, Cleveland, (1973)
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6.3 Thermodynamics Page 248 Wednesday, December 31, 1969 17:00
Thermodynamic and Kinetic Data
Table 73. HEAT OF
FUSION FOR ELEMENTS AND INORGANIC COMPOUNDS (SHEET 9 OF 16)
Compound
Formula
Molybdenum hexafluoride Molybdenum trioxide Neodymium Neon
MoF6 MoO3 Nd Ne
Nickel Nickel chloride
Ni NiCl2
Nickel subsulfide Niobium
Ni3S2 Nb
Niobium pentachloride
NbCl5
Niobium pentoxide Nitric oxide Nitrogen
Nb2O5 NO N2
Nitrogen tetroxide
N2O4
Nitrous oxide Osmium Osmium tetroxide (white)
N 2O Os OsO4
Osmium tetroxide (yellow) Oxygen Palladium Phosphoric acid
OsO4 O2 Pd H3PO4
Heat of fusion
Melting point ˚C
cal/g
cal/g mole
17 795
11.9 (17.3)
2500 (2500)
1020 – 248.6
11.8 3.83
1700 77.4
1452
71.5
4200
1030 790
142 5 25.8 1
18470 5800
2496
(68.9)
(6500)
21.1 1511
30 8 91.0
8400 24200
–163.7
18.3
549.5
–210
6.15
172.3
–13.2 –90.9
60.2 35.5
5540 1563
2700
(36.7)
(7000)
41.8
9.2
2340
55.8 –218.8
15.5 3.3
4060 106.3
1555
38.6
4120
42.3
25.8
2520
For heat of fusion in J/kg, multiply values in cal/g by 4184. For heat of fusion in J/mol, multiply values in cal/g-mol (=cal/mol) by 4.184. For melting point in K, add 273.15 to values in ˚C. Values in parentheses are of uncertain reliability. Source: data from Weast, R C., Ed., Handbook of Chemistry and Physics, 55th ed., CRC Press, Cleveland, (1974); and Bolz, R. E. and Tuve, G. L., Eds., Handbook of Tables for Applied Engineering Science, 2nd ed., CRC Press, Cleveland, (1973)
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6.3 Thermodynamics Page 249 Wednesday, December 31, 1969 17:00
Thermodynamic and Kinetic Data
Table 73. HEAT OF
FUSION FOR ELEMENTS AND INORGANIC COMPOUNDS (SHEET 10 OF 16)
Compound
Formula
Phosphoric acid. hypo–
H4P2O6
Phosphorus acid, hypo–
H3PO2
Phosphorus acid, ortho– Phosphorus oxychloride
H3PO3 POCl3
Phosphorus pentoxide
P4O10
Phosphorus trioxide Phosphorus, yellow Platinum
P4O6 P4 Pt
Potassium Potassium borate, meta– Potassium bromide Potassium carbonate
K KBO2 KBr K2CO3
Potassium chloride Potassium chromate Potassium cyanide Potassium dichromate
KCl K2CrO4 KCN K2Cr2O7
Potassium fluoride Potassium hydroxide Potassium iodide Potassium nitrate
KF KOH Kl KNO3
Heat of fusion
Melting point ˚C
cal/g
cal/g mole
54.8 17.3 73.8 1.0
51.2 35.0 37.4 20.3
8300 2310 3070 3110
569.0 23.7 44.1
60.1 15.3 4.8
17080 3360 600
1770
24.1
4700
63.4
14.6
574
947
(69.1)
(5660)
742
42.0
5000
897
56.4
7800
770
85.9
6410
984
35.6
6920
623
(53.7)
(3500)
398
29.8
8770
875 360 682
111.9 (35.3) 24.7
6500 (1980) 4100
338
78.1
2840
For heat of fusion in J/kg, multiply values in cal/g by 4184. For heat of fusion in J/mol, multiply values in cal/g-mol (=cal/mol) by 4.184. For melting point in K, add 273.15 to values in ˚C. Values in parentheses are of uncertain reliability. Source: data from Weast, R C., Ed., Handbook of Chemistry and Physics, 55th ed., CRC Press, Cleveland, (1974); and Bolz, R. E. and Tuve, G. L., Eds., Handbook of Tables for Applied Engineering Science, 2nd ed., CRC Press, Cleveland, (1973)
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Thermodynamic and Kinetic Data
Table 73. HEAT OF
FUSION FOR ELEMENTS AND INORGANIC COMPOUNDS (SHEET 11 OF 16)
Compound
cal/g
cal/g mole
490 1340 1092 1074
55.3 41.9 42.4 46.4
6100 8900 14000 8100
179 931 3167±60
23.1 19.0 (42.4)
2250 2700 (7900)
296
30.1
15340
Formula
Potassium peroxide
K2O2
Potassium phosphate
K3PO4
Potassium pyro– phosphate
K4P2O7
Potassium sulfate
K2SO4
Potassium thiocyanate Praseodymium Rhenium Rhenium heptoxide
KSCN Pr Re Re2O7
Rhenium hexafluoride Rubidium Rubidium bromide Rubidium chloride
ReF6 Rb RbBr RbCl
Rubidium fluoride Rubidium iodide Rubidium nitrate Samarium
RbF Rbl RbNO3 Sm
Scandium Selenium Seleniumoxychloride
Sc Se SeOCl3
Silane, hexaHuoro–
Si2F6
Heat of fusion
Melting point ˚C
19.0
16.6
5000
38 .9 677 717
6. 1 22.4 36.4
525 3700 4400
833 638
39.5 14.0
4130 2990
305
9.1
1340
1072
17.3
2600
1538 217
84.4 15.4
3800 1220
9.8 –28.6
6.1 22.9
1010 3900
For heat of fusion in J/kg, multiply values in cal/g by 4184. For heat of fusion in J/mol, multiply values in cal/g-mol (=cal/mol) by 4.184. For melting point in K, add 273.15 to values in ˚C. Values in parentheses are of uncertain reliability. Source: data from Weast, R C., Ed., Handbook of Chemistry and Physics, 55th ed., CRC Press, Cleveland, (1974); and Bolz, R. E. and Tuve, G. L., Eds., Handbook of Tables for Applied Engineering Science, 2nd ed., CRC Press, Cleveland, (1973)
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6.3 Thermodynamics Page 251 Wednesday, December 31, 1969 17:00
Thermodynamic and Kinetic Data
Table 73. HEAT OF
FUSION FOR ELEMENTS AND INORGANIC COMPOUNDS (SHEET 12 OF 16)
Compound
Heat of fusion
Formula
Melting point ˚C
cal/g
cal/g mole
Silicon Silicon dioxide (Cristobalite) Silicon tetrachloride Silver
Si
1427
337.0
9470
SiO2
1723
35.0
2100
SiCl4 Ag
–67.7
10.8
1845
961
25.0
2700
Silver bromide Silver chloride Silver cyanide Silver iodide
AgBr AgCl AgCN AgI
430 455 350 557
11.6 22.0 20.5 9.5
2180 3155 2750 2250
Silver nitrate
AgNO3
209 657 841
16.2 (13.7) 13.5
2755 (4280) 3360
97.8
27.4
630
8660
Silver sulfate
Ag2SO4
Silver sulfide Sodium
Ag2S Na
Sodium borate, meta– Sodium bromide Sodium carbonate
966
134.6
747
59.7
6140
Sodium chlorate
NaBO2 NaBr Na2CO3 NaClO3
854 255
66.0 49.7
7000 5290
Sodium chloride Sodium cyanide Sodium fluoride Sodium hydroxide
NaCl NaCN NaF NaOH
800 562 992 322
123.5 (88.9) 166.7 50.0
7220 (4360) 7000 2000
For heat of fusion in J/kg, multiply values in cal/g by 4184. For heat of fusion in J/mol, multiply values in cal/g-mol (=cal/mol) by 4.184. For melting point in K, add 273.15 to values in ˚C. Values in parentheses are of uncertain reliability. Source: data from Weast, R C., Ed., Handbook of Chemistry and Physics, 55th ed., CRC Press, Cleveland, (1974); and Bolz, R. E. and Tuve, G. L., Eds., Handbook of Tables for Applied Engineering Science, 2nd ed., CRC Press, Cleveland, (1973)
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251
6.3 Thermodynamics Page 252 Wednesday, December 31, 1969 17:00
Thermodynamic and Kinetic Data
Table 73. HEAT OF
FUSION FOR ELEMENTS AND INORGANIC COMPOUNDS (SHEET 13 OF 16)
Compound
Formula
Sodium iodide Sodium molybdate Sodium nitrate Sodium peroxide
NaI Na2MoO4 NaNO3
Sodium phosphate, meta– Sodium pyrophosphate
NaPO3 Na4P2O7
Sodiumsilicate,aluminum–
NaAlSi3O8
Sodium silicate, di–
Na2Si2O5
Sodium silicate, meta–
Na2SiO3
Na2O2
Melting point ˚C
Heat of fusion cal/g
cal/g mole
662
35.1
5340
687 310 460
17.5 44.2 75.1
3600 3760 5860
988 970 1107 884
(48.6) (51.5) 50.1 46.4
(4960) (13700) 13150 8460
1087 884 920
84.4 41.0 15.4
10300 5830 (1200)
323
54.8
4450
5800
Sodium sulfate
Na2SO4
Sodium sulfide Sodium thiocyanate
Na2S NaSCN
Sodium tungstate Strontium Strontium bromide Strontium chloride
Na2WO4 Sr SrBr2 SrCl2
702
19.6
757
25.0
2190
643 872
19.3 26.5
4780 4100
Strontium fluoride Strontium oxide Sulfur (monatomic) Sulfur dioxide
SrF2 SrO S SO2
1400
34.0
4260
2430 119
161.2 9.2
16700 295
–73.2
32.2
2060
For heat of fusion in J/kg, multiply values in cal/g by 4184. For heat of fusion in J/mol, multiply values in cal/g-mol (=cal/mol) by 4.184. For melting point in K, add 273.15 to values in ˚C. Values in parentheses are of uncertain reliability. Source: data from Weast, R C., Ed., Handbook of Chemistry and Physics, 55th ed., CRC Press, Cleveland, (1974); and Bolz, R. E. and Tuve, G. L., Eds., Handbook of Tables for Applied Engineering Science, 2nd ed., CRC Press, Cleveland, (1973)
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6.3 Thermodynamics Page 253 Wednesday, December 31, 1969 17:00
Thermodynamic and Kinetic Data
Table 73. HEAT OF
FUSION FOR ELEMENTS AND INORGANIC COMPOUNDS (SHEET 14 OF 16) Heat of fusion
Compound
Formula
Melting point ˚C
Sulfur trioxide (α)
SO3 SO3 SO3
16.8 32.3 62.1
25.8 36.1 79.0
2060 2890 6310
Ta
2996 ± 50
34.6–41.5
(7500)
TaCl5
206.8 1877
25.1 108.6
9000 48000
453 1356
25.3 24.6
3230 3900
302.4 460
5.0 21.0
1030 5990
273
9.5
4400
427
17.7
4260
Sulfur trioxide (β) Sulfur trioxide (γ) Tantalum Tantalum pentachloride Tantalum pentoxide Tellurium Terbium
Ta2O5 Te Tb
Thallium Thallium bromide, mono– Thallium carbonate Thallium chloride, mono–
Tl TlBr Tl2CO3 TICl
Thallium iodide, mono– Thallium nitrate
TlI TINO3
Thallium sulfate
Tl2SO4
Thallium sulfide
Tl2S
Thorium Thorium chloride Thorium dioxide Thulium
Th ThCl4 ThO2 Tm
cal/g
cal/g mole
440
9.4
3125
207 632 449
8.6 10.9 6.8
2290 5500 3000
1845
(1030 940–1030 A95 (Shore) M87 M71—95 75 (Barcol) E94—97, M116—120 M116—120
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
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8.18 Mechanical Page 735 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 206. HARDNESS OF
SI3N4 AND AL2O3 COMPOSITES
Matrix
Dispersed Phase
Knoop Hardness (GPa)
Si3N4+ 6 wt % Y2O3
None
13.4 ± 0.3
Si3N4+ 6 wt % Y2O3
TiC (Ti, W) C WC
15.21 ± 0.3 14.06 ± 0.3 14.4 ± 0.4
TaC HfC SiC
12.6 ± 0.2 14.1 ± 0.4 13.6 ± 0.2
TiC
17.2 ± 0.2
Al2O3
Containing 30 Vol % of Metal Carbide Dispersoid (2 µm average particle diameter) Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p169,(1994).
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8.18 Mechanical Page 736 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 207. COEFFICIENT OF
STATIC FRICTION FOR POLYMERS
Class
Polymer
Coefficient of Static Friction (Against Self) (Dimensionless)
ABS–Polycarbonate Alloy
ABS–Polycarbonate Alloy
0.2
Polycarbonates
Polycarbonate
0.52
Nylons; Molded, Extruded
Type 6
Polyacetals
Cast
0.32 (dynamic )
6/6 Nylon General purpose molding
0.04—0.13
Homopolymer: Standard 20% glass reinforced 22% TFE reinforced Copolymer: Standard 25% glass reinforced High flow
Polyester; Thermoplastic
0.15 (against steel) 0.15 (against steel) 0.15 (against steel) (ASTM D1894)
Injection Moldings: General purpose grade Glass reinforced grades Glass reinforced self extinguishing Polyester; Thermoplastic
0.1—0.3 (against steel) 0.1—0.3 (against steel) 0.05—0.15 (against steel)
Injection Moldings: General purpose grade Glass reinforced grades Glass reinforced self extinguishing
0.17 0.16 0.16
0.13 (against steel) 0.14 (against steel) 0.14 (against steel)
Phenylene oxides (Noryl)
Standard
0.67
Polyarylsulfone
Polyarylsulfone
0.1—0.3
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3 , CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
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CRC Handbook of Materials Science & Engineering
8.18 Mechanical Page 737 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 208. ABRASION RESISTANCE OF (SHEET 1 OF 2)
POLYMERS
Class
Polymer
Abrasion Resistance (Taber, CS—17 wheel, ASTM D1044) (mg / 1000 cycles)
Fluorocarbons; Molded,Extruded
Polytrifluoro chloroethylene (PTFCE)
0.008 (g/cycle)
Polyvinylidene— fluoride (PVDF)
0.0006—0.0012 (g/cycle)
Polycarbonate Polycarbonate (40% glass fiber reinforced)
10
Polycarbonates
Nylons; Molded, Extruded Type 6 General purpose Cast Nylons; Molded, Extruded
40
5 2.7
6/6 Nylon General purpose molding General purpose extrusion
3—8 3—5
PVC–Acrylic Alloy
PVC–acrylic sheet PVC–acrylic injection molded
0.073 (CS—10 wheel) 0.0058 (CS—10 wheel)
Polymides
Unreinforced Unreinforced 2nd value Glass reinforced
0.08 0.004 20
Polyacetals
Homopolymer: Standard 20% glass reinforced 22% TFE reinforced Copolymer: Standard 25% glass reinforced High flow
14—20 33 9 14 40 14
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
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737
8.18 Mechanical Page 738 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 208. ABRASION RESISTANCE OF (SHEET 2 OF 2)
POLYMERS Abrasion Resistance (Taber, CS—17 wheel, ASTM D1044) (mg / 1000 cycles)
Class
Polymer
Polyester; Thermoplastic
Injection Moldings: General purpose grade Glass reinforced grades Glass reinforced self extinguishing
6.5 9—50 11
Phenylene Oxides
SE—100 SE—1 Glass fiber reinforced
100 20 35
Phenylene oxides (Noryl)
Standard
20
Polyarylsulfone
Polyarylsulfone
40
Polystyrenes; Molded
Glass fiber -30% reinforced
164
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
738
CRC Handbook of Materials Science & Engineering
8.18 Mechanical Page 739 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 209. FATIGUE
STRENGTH OF WROUGHT ALUMINUM ALLOYS (SHEET 1 OF 4) Alloy AA No.
Temper
Fatigue Strength (MPa)
1060
0 H12 H14 H16 H18
21 28 34 45 45
1100
0 H12 H14 H16 H18
34 41 48 62 62
1350 2011
H19 T3 T8
48 125 125
2014
0 T4 T6
90 140 125
2024
0 T3 T4, T351 T361
90 140 140 125
2036 2048
T4
125 220
2219
T62 T81, T851 T87
105 105 105
2618 3003 Alclad
All 0 H12
125 48 55
Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, (1984).
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739
8.18 Mechanical Page 740 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 209. FATIGUE
STRENGTH OF WROUGHT ALUMINUM ALLOYS (SHEET 2 OF 4) Alloy AA No.
Temper
Fatigue Strength (MPa)
3003
H14 H16 H18
62 69 69
3004 Alclad
0 H32
97 105
3004
H34 H36 H38 T6
105 110 110 110
5050
0 H32 H34 H36 H38
83 90 90 97 97
5052
0 H32 H34 H36 H38
110 115 125 130 140
5056
0 H18 H38 H321
140 150 150 160
5154
0 H32 H34 H36 H38 H112
115 125 130 140 145 115
5182 5254
0 0
140 115
4032
5083
Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, (1984).
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740
CRC Handbook of Materials Science & Engineering
8.18 Mechanical Page 741 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 209. FATIGUE
STRENGTH OF WROUGHT ALUMINUM ALLOYS (SHEET 3 OF 4) Alloy AA No.
Temper
Fatigue Strength (MPa)
5254
H32 H34 H36 H38 H112
125 130 140 145 115
5652
0 H32 H34 H36 H38
110 115 125 130 140
6005
T1 T5
97 97
6009 6010
T4 T4
115 115
6061
0 T4, T451 T6, T651
62 97 97
6063
0 T1 T5 T6
55 62 69 69
6066 6070
T6, T651 0 T4 T6
110 62 90 97
6205 6262 6351
T5 T9 T6
105 90 90
Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, (1984).
©2001 CRC Press LLC Shackelford & Alexander
741
8.18 Mechanical Page 742 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 209. FATIGUE
STRENGTH OF WROUGHT ALUMINUM ALLOYS (SHEET 4 OF 4) Alloy AA No.
Temper
Fatigue Strength (MPa)
6463
T1 T5 T6
69 69 69
7005
T53 T6,T63,T6351
140 125
7049 7050 7075
T73 T736 T6,T651
295 240 160
7175
T66 T736 T7351
160 160 220
7475
Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, (1984).
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742
CRC Handbook of Materials Science & Engineering
8.18 Mechanical Page 743 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 210. REVERSED
BENDING FATIGUE LIMIT OF GRAY CAST IRON BARS
ASTM Class
Reversed Bending Fatigue Limit (MPa)
20 25 30
69 79 97
35 40 50 60
110 128 148 169
Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, p166-167, (1984).
©2001 CRC Press LLC Shackelford & Alexander
743
8.18 Mechanical Page 744 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 211. IMPACT ENERGY OF (SHEET 1 OF 2)
TOOL STEELS
Type
Condition
Impact Energy (J)
L2
Oil quenched from 855 ˚C and single tempered at: 205 ˚C 315 ˚C 425 ˚C 540 ˚C 650 ˚C
28(a) 19(a) 26(a) 39(a) 125(a)
Annealed
93 HRB
Oil quenched from 845 ˚C and single tempered at: 315 ˚C 425 ˚C 540 ˚C 650 ˚C
12(a) 18(a) 23(a) 81(a)
L6
S1
S5
Oil quenched from 930 ˚C and single tempered at: 205 ˚C 315 ˚C 425 ˚C 540 ˚C 650 ˚C
249(b) 233(b) 203(b) 230(b)
Oil quenched from 870 ˚C and single tempered at: 205 ˚C 315 ˚C 425 ˚C 540 ˚C 650 ˚C
206(b) 232(b) 243(b) 188(b)
(a) Charpy V-notch. (b) Charpy unnotched. Source: Data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, p241, (1984).
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CRC Handbook of Materials Science & Engineering
8.18 Mechanical Page 745 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 211. IMPACT ENERGY OF (SHEET 2 OF 2)
TOOL STEELS
Type
Condition
Impact Energy (J)
S7
Fan cooled from 940 ˚C and single tempered at: 205 ˚C 315 ˚C 425 ˚C 540 ˚C 650 ˚C
244(b) 309(b) 243(b) 324(b) 358(b)
(a) Charpy V-notch. (b) Charpy unnotched. Source: Data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, p241, (1984).
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8.19 Mechanical L Page 746 Wednesday, December 31, 1969 17:00
Table 212. IMPACT
STRENGTH OF WROUGHT TITANIUM ALLOYS AT ROOM TEMPERATURE
Class
Alloy
Condition
Charpy Impact Strength (J)
Commercially Pure
99.2Ti 99.1Ti 99.0 Ti 99.2Ti-0.2Pd
Annealed Annealed Annealed Annealed
43 38 20 43
Alpha Alloys
Ti-5Al-2.5Sn Ti-5Al-2.5Sn (low O2)
Annealed Annealed
26 27
Near alpha alloys
Ti-8Al-1Mo-1V Ti-6Al-2Nb-1Ta-1Mo
Duplex Annealed As rolled 2.5 cm (1 in.) plate
32 31
Alpha-Beta Alloys
Ti-6Al-4V Ti-6Al-4V(low O2) Ti-6Al-6V-2Sn Ti-7Al-4Mo
Annealed Annealed Annealed Solution + age
19 24 18 18
Beta Alloys
Ti-13V-1Cr-3Al Ti-3Al-8V-6Cr-4Mo-4Zr
Solution + age Solution + age
11 10
Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p512, (1993).
©2001 CRC Press LLC
8.20 Mechanical Page 747 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 213. IMPACT STRENGTH OF (SHEET 1 OF 7)
POLYMERS
Class
Polymer
Impact Strength (Izod notched, ASTM D256) (ft—lb / in.)
ABS Resins; Molded, Extruded
Medium impact
2.0—4.0
High impact Very high impact Low temperature impact Heat resistant
3.0—5.0 5.0—7.5 6—10 2.0—4.0
Acrylics; Cast, Molded, Extruded
Cast Resin Sheets, Rods: General purpose, type I General purpose, type II
0.4 0.4
Moldings: Grades 5, 6, 8 High impact grade
0.2—0.4 0.8—2.3
Thermoset Carbonate
Allyl diglycol carbonate
0.2—0.4
Alkyds; Molded
Putty (encapsulating) Rope (general purpose) Granular (high speed molding) Glass reinforced (heavy duty parts)
0.25—0.35 2.2
Cellulose Acetate Butyrate; Molded, Extruded
0.30—0.35 8—12
ASTM Grade: H4 MH S2
3 4.4—6.9 7.5—10.0
To convert ft—lb / in. to N•m/m, multiply by 53.38 Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC Shackelford & Alexander
747
8.20 Mechanical Page 748 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 213. IMPACT STRENGTH OF (SHEET 2 OF 7)
Class
Polymer
Cellusose Acetate Propionate; Molded, Extruded
ASTM Grade:
Chlorinated Polymers
Polycarbonate Diallyl Phthalates; Molded
Fluorocarbons; Molded,Extruded
Epoxies; Cast, Molded, Reinforced
POLYMERS
Impact Strength (Izod notched, ASTM D256) (ft—lb / in.)
1 3 6
1.7—2.7 3.5—5.6 9.4
Chlorinated polyether Chlorinated polyvinyl chloride
0.4 (D758)
Polycarbonate
12—16
6.3
Orlon filled
0.5—1.2
Dacron filled Asbestos filled Glass fiber filled
1.7—5.0 0.30—0.50 0.5—15.0
Polytrifluoro chloroethylene (PTFCE) Polytetrafluoroethylene (PTFE) Fluorinated ethylene propylene(FEP) Polyvinylidene— fluoride (PVDF)
3.50—3.62
Standard epoxies (diglycidyl ethers of bisphenol A) Cast rigid Cast flexible
2.0—4.0 No break 3.0—10.3
0.2—0.5 0.3—0.2
To convert ft—lb / in. to N•m/m, multiply by 53.38 Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
748
CRC Handbook of Materials Science & Engineering
8.20 Mechanical Page 749 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 213. IMPACT STRENGTH OF (SHEET 3 OF 7)
POLYMERS
Class
Polymer
Impact Strength (Izod notched, ASTM D256) (ft—lb / in.)
Epoxies; Cast, Molded, Reinforced (Con’t)
Molded
0.4—0.5
General purpose glass cloth laminate High strength laminate
12—15
Epoxies—Molded, Extruded
60—61
High performance resins (cycloaliphatic diepoxides) Cast, rigid Molded
0.5 0.3—0.5
Epoxy novolacs
Cast, rigid
13—17
Melamines; Molded
Filler & type Cellulose electrical Glass fiber Alpha cellulose and mineral
0.27—0.36 0.5—12.0 0.30—0.35, 0.2(mineral)
Nylons; Molded, Extruded
Type 6 General purpose Glass fiber (30%) reinforced Cast Flexible copolymers
0.6—1.2 2.2—3.4 1.2 1.5—19
Type 8 Type 11 Type 12
>16 3.3—3.6 1.2—4.2
6/6 Nylon General purpose molding Glass fiber reinforced General purpose extrusion
(ASTM D638) 0.55—1.0,2.0 2.5—3.4 1.3
To convert ft—lb / in. to N•m/m, multiply by 53.38 Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC Shackelford & Alexander
749
8.20 Mechanical Page 750 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 213. IMPACT STRENGTH OF (SHEET 4 OF 7)
Class
Polymer
Nylons; Molded, Extruded (Con’t)
6/10 Nylon
Impact Strength (Izod notched, ASTM D256) (ft—lb / in.)
General purpose Glass fiber (30%) reinforced Phenolics; Molded
POLYMERS
Type and filler General: woodflour and flock Shock: paper, flock, or pulp High shock: chopped fabric or cord Very high shock: glass fiber
0.6–1.6 3.4
0.24—0.50 0.4—1.0 0.6—8.0 10—33
Arc resistant—mineral Rubber phenolic— woodflour or flock Rubber phenolic—chopped fabric Rubber phenolic—asbestos
0.30—0.45
ABS–Polycarbonate Alloy
ABS–Polycarbonate Alloy
10 (ASTM D638)
PVC–Acrylic Alloy
PVC–acrylic sheet PVC–acrylic injection molded
15
Unreinforced Unreinforced 2nd value Glass reinforced
0.5 0.5 17
Polymides
Polyacetals
0.34—1.0 2.0—2.3 0.3—0.4
15
(ASTM D638) Homopolymer: Standard 20% glass reinforced 22% TFE reinforced
1.4 0.8 0.7
To convert ft—lb / in. to N•m/m, multiply by 53.38 Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
750
CRC Handbook of Materials Science & Engineering
8.20 Mechanical Page 751 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 213. IMPACT STRENGTH OF (SHEET 5 OF 7)
POLYMERS
Class
Polymer
Impact Strength (Izod notched, ASTM D256) (ft—lb / in.)
Polyacetals (Con’t)
Copolymer: Standard 25% glass reinforced High flow
1.3 1.8 1
Polyester; Thermoplastic
Polyesters: Thermosets
Injection Moldings: General purpose grade Glass reinforced grades Glass reinforced self extinguishing
1.8
General purpose grade Glass reinforced grade Asbestos—filled grade
1 1 0.5
Cast polyyester Rigid Flexible
0.18—0.40 4
Reinforced polyester moldings High strength (glass fibers) Heat and chemical resistsnt (asbestos) Sheet molding compounds, general purpose Phenylene Oxides
Phenylene oxides (Noryl)
1.0—1.2 1.3—2.2
1—10 0.45—1.0 5—15
SE—100 SE—1 Glass fiber reinforced
(ASTM D638) 5 5 2.3
Standard
1.2—1.3
Glass fiber reinforced
1.8—2.0
To convert ft—lb / in. to N•m/m, multiply by 53.38 Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
Shackelford & Alexander
751
8.20 Mechanical Page 752 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 213. IMPACT STRENGTH OF (SHEET 6 OF 7)
POLYMERS
Class
Polymer
Impact Strength (Izod notched, ASTM D256) (ft—lb / in.)
Polyarylsulfone
Polyarylsulfone
1.6—5.0
Polypropylene
General purpose High impact
0.4—2.2 1.5—12
Asbestos filled Glass reinforced Flame retardant
0.5—1.5 0.5—2 2.2
Polyphenylene sulfide
Standard 40% glass reinforced
0.3 1.09
Polyethylenes; Molded, Extruded
Type III—higher density (0.941—0.965) Melt index 0.2—0.9 Melt Melt index 0.l—12.0 Melt index 1.5—15 High molecular weight
4.0—14 0.4—6.0 1.2—2.5 >20
Ethylene butene
0.4
Propylene—ethylene Ionomer Polyallomer
1.1 9—14 1.5
Polystyrenes General purpose Medium impact High impact
(ASTM D638) 0.2—0.4 0.5—1.2 0.8—1.8
Glass fiber —30% reinforced Styrene acrylonitrile (SAN) Glass fiber (30%) reinforced SAN
2.5 0.29—0.54
Olefin Copolymers; Molded
Polystyrenes; Molded
1.35—3.0
To convert ft—lb / in. to N•m/m, multiply by 53.38 Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
752
CRC Handbook of Materials Science & Engineering
8.20 Mechanical Page 753 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 213. IMPACT STRENGTH OF (SHEET 7 OF 7)
POLYMERS
Class
Polymer
Impact Strength (Izod notched, ASTM D256) (ft—lb / in.)
Polyvinyl Chloride And Copolymers; Molded, Extruded
Nonrigid—general
Variable
Nonrigid—electrical Rigid—normal impact Vinylidene chloride
Variable 0.5—10 2—8
Fibrous (glass) reinforced silicones Granular (silica) reinforced silicones Woven glass fabric/ silicone laminate
10
Silicones; Molded, Laminated
Ureas; Molded
Alpha—cellulose filled (ASTM Type l) Cellulose filled (ASTM Type 2) Woodflour filled
0.34 10—25 0.20—0.35 0.20—0.275 0.25—0.35
To convert ft—lb / in. to N•m/m, multiply by 53.38 Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC Shackelford & Alexander
753
8.20 Mechanical Page 754 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 214. IMPACT
STRENGTH OF FIBERGLASS REINFORCED PLASTICS Class
Material
Glass fiber content (wt%)
Glass fiber reinforced thermosets
Sheet molding compound (SMC)
15 to 30
8 to 22
Bulk molding compound(BMC) Preform/mat(compression molded) Cold press molding–polyester
15 to 35 25 to 50 20 to 30
2 to 10 10 to 20 9 to 12
Spray–up–polyester Filament wound–epoxy Rod stock–polyester Molding compound–phenolic
30 to 50 30 to 80 40 to 80 5 to 25
4 to 12 40 to 60 45 to 60 1 to 8
Glass–fiber–reinforced thermoplastics
Izod Impact strength (ft • Ib/in. of notch)
Acetal
20 to 40
0.8 to 2.8
Nylon Polycarbonate Polyethylene
6 to 60 20 to 40 10 to 40
0.8 to 4.5 1.5 to 3.5 1.2 to 4.0
Polypropylene Polystyrene Polysulfone ABS(acrylonitrile butadiene styrene)
20 to 40 20 to 35 20 to 40 20 to 40
1 to 4 0.4 to 4.5 1.3 to 2.5 1 to 2.4
PVC (polyvinyl chloride) Polyphenylene oxide(modified) SAN (styrene acrylonitrile) Thermoplastic polyester
15 to 35 20 to 40 20 to 40 20 to 35
0.8 to 1.6 1.6 to 2.2 0.4 to 2.4 1.0 to 2.7
To convert (ft • Ib/in. of notch) to (J/cm of notch), multiply by 0.534 Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p106, (1994).
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CRC Handbook of Materials Science & Engineering
8.20 Mechanical Page 755 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 215. IMPACT
STRENGTH OF CARBON - AND GLASS REINFORCED ENGINEERING THERMOPLASTICS (SHEET 1 OF 2) Class
Resin Type
Composition
Impact Strength, Notched/Unnotched (J/cm)
Amorphous
Acrylonitrile-butadiene-styrene(ABS)
30% glass fiber 30% carbon fiber
0.75/3.5 0.59/2.4
Nylon
30% glass fiber 30% carbon fiber
0.64/3.7 0.64/4.3
Polycarbonate
30% glass fiber 30% carbon fiber
2.0/9.34 0.96/5.34
Polyetherimide
30% glass fiber 30% carbon fiber
0.75/5.60 0.75/6.67
Polyphenylene oxide (PPO)
30% glass fiber 30% carbon fiber
1.2/5.1 0.53/3.0
Polysulfone
30% glass fiber 30% carbon fiber
0.96/7.5 0.64/3.5
Styrene-maleic-anhydride (SMA)
30% glass fiber
0.59/2.4
Thermoplastic polyurethane
30% glass fiber
5.1/15
Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p111–112, (1994).
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Shackelford & Alexander
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8.20 Mechanical Page 756 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 215. IMPACT
STRENGTH OF CARBON - AND GLASS REINFORCED ENGINEERING THERMOPLASTICS (SHEET 2 OF 2) Class
Resin Type
Composition
Impact Strength, Notched/Unnotched (J/cm)
Crystalline
Acetal
30% glass fiber 20% carbon fiber
0.96/4.8 0.53/1.6
Nylon 66
30% glass fiber 30% carbon fiber
1.5/11 0.80/6.4
Polybutylene telphthalate (PBT)
30% glass fiber 30% carbon fiber
1.4/9.1 0.64/3.5
Polythylene terephthalate (PET)
30% glass fiber
1.0/—
Polyphenylene sulfide (PPS)
30% glass fiber 30% carbon fiber
0.75/4.5 0.59/2.9
Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p111–112, (1994).
©2001 CRC Press LLC
756
CRC Handbook of Materials Science & Engineering
8.20 Mechanical Page 757 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 216. FRACTURE
TOUGHNESS OF SI3N4 AND AL2O3 COMPOSITES
Matrix
Dispersed Phase
Fracture Toughness (KIc), (MPa √m)
Si3N4+ 6 wt % Y2O3
None
4.8 ± 0.3
Si3N4+ 6 wt % Y2O3
TiC (Ti, W) C WC
4.4 ± 0.5 3.5 ± 0.3 5.2 ± 0.4
TaC HfC SiC
4.6 ± 0.4 3.6 ± 0.2 3.65 ± 0.5
TiC
3.2 ± 0.4
Al2O3
Containing 30 Vol % of Metal Carbide Dispersoid (2 µm average particle diameter) Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p169,(1994).
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Shackelford & Alexander
757
8.20 Mechanical Page 758 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 217. TENSILE
MODULUS OF GRAY CAST IRONS
ASTM Class
Tensile Modulus (GPa)
20 25 30 35
66 to 97 79 to 102 90 to 113 100 to 119
40 50 60
110 to 138 130 to 157 141 to 162
Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, p166-167, (1984).
Table 218. TENSION
MODULUS OF TREATED DUCTILE IRONS
Treatment
Tension Modulus (MPa)
60-40-18 65-45-12 80-55-06 120 90-02
169 168 168 164
Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, p169-170, (1984).
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CRC Handbook of Materials Science & Engineering
8.20 Mechanical Page 759 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 219. TENSILE
MODULUS OF FIBERGLASS REINFORCED PLASTICS Tensile modulus (105 psi)
Class
Material
Glass fiber content (wt%)
Glass fiber reinforced thermosets
Sheet molding compound (SMC)
15 to 30
16 to 25
Bulk molding compound(BMC) Preform/mat(compression molded)
15 to 35 25 to 50
16 to 25 9 to 20
Spray–up–polyester Filament wound–epoxy Rod stock–polyester Molding compound–phenolic
30 to 50 30 to 80 40 to 80 5 to 25
8 to l8 40 to 90 40 to 60 26 to 29
Acetal
20 to 40
8 to 15
Nylon Polycarbonate Polyethylene
6 to 60 20 to 40 10 to 40
2 to 20 7.5 to 17 4 to 9
Polypropylene Polystyrene Polysulfone ABS(acrylonitrile butadiene styrene)
20 to 40 20 to 35 20 to 40 20 to 40
4.5 to 9 8.4 to 12.1 15 6 to 10
PVC (polyvinyl chloride) Polyphenylene oxide(modified) SAN (styrene acrylonitrile) Thermoplastic polyester
15 to 35 20 to 40 20 to 40 20 to 35
10 to 18 9.5 to 15 9 to 18.5 13 to 15.5
Glass–fiber–reinforced thermoplastics
To convert from psi to MPa, multiply by 145. Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p106, (1994).
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759
8.20 Mechanical Page 760 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 220. TENSILE
MODULUS OF GRAPHITE /ALUMINUM COMPOSITES Composite
Fiber loading (vol %)
Wire diameter (mm)
Tensile Modulus (GPa)
VS0054/201 Al GY70SE/201 Al
48 to 52 37 to 38
0.64 (2-strand) 0.71(8-strand)
345 207
Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p148,(1994).
Table 221. TENSILE
MODULUS OF INVESTMENT CAST SILICON CARBIDE SCS–AL Fiber orientation
Fiber vol (%)
Tensile Modulus (GPa)
Range of Measurement (%)
0°3/90°6/0°3 90°3/0°6/90°3 0°
33 33 34
122.0 124.8 172.4
107 110 100
Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p149,(1994).
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CRC Handbook of Materials Science & Engineering
8.20 Mechanical Page 761 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 222. TENSILE
MODULUS OF SILICON CARBIDE SCS–2–AL
Fiber orientation
No. of plies
Tensile Modulus (GPa)
0° 90°
6, 8, 12 6, 12,40
204.1 118.0
[0°/90°/0°/90°]s [02 °99°20°]s [902/0°/90°]s
8 8 8
136.5 180.0 96.5
± 45° [0°±45°/0°]s+2s [0°±45°/90°]s
8, 12, 40 8, 16 8
94.5 146.2 127.0
Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p149,(1994).
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761
8.20 Mechanical Page 762 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 223. YOUNG’S MODULUS OF (SHEET 1 OF 7) Class
Ceramic
Borides
Chromium Diboride (CrB2)
CERAMICS
Young’s Modulus (psi)
Tantalum Diboride (TaB2)
30.6x106 37 x106
Titanium Diboride (TiB2)
53.2x106
(6.0 µm grain size, ρ=4.46g/cm3)
81.6x106
(3.5 µm grain size, ρ=4.37g/cm3,
75.0x106
0.8wt% Ni) (6.0 µm grain size, ρ=4.56g/cm3, 0.16wt% Ni) (12.0 µm grain size, ρ=4.66g/cm3, 9.6wt% Ni)
Carbides
Temperature
77.9x106 6.29x106
Zirconium Diboride (ZrB2)
49.8-63.8x106
(22.4% density,foam)
3.305x106
Boron Carbide (B4C)
42-65.2x106
room temp.
(ρ = 11.94 g/cm3)
61.55x106
room temp.
Silicon Carbide (SiC) (pressureless sintered)
43.9x106
room temp. room temp. room temp. room temp.
Hafnium Monocarbide (HfC)
(hot pressed)
63.8x106
(self bonded)
59.5x106
(cubic, CVD)
60.2-63.9x106
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991)
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CRC Handbook of Materials Science & Engineering
8.20 Mechanical Page 763 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 223. YOUNG’S MODULUS OF (SHEET 2 OF 7)
CERAMICS
Class
Ceramic
Young’s Modulus (psi)
Temperature
Carbides (Con’t)
(ρ = 3.128 g/cm3)
58.2x106
room temp.
(ρ = 3.120 g/cm3) (hot pressed)
59.52x106 62.4-65.3x106
(sintered)
54.38-60.9x106
room temp. 20˚C 20˚C
(reaction sintered)
50.75-54.38x106 55x106 53x106 51x106 55.1x106
20˚C 400˚C 800˚C 1200˚C
(sintered)
43.5-58.0x10
(reaction sintered)
29-46.4x106
1400˚C 1400˚C 1400˚C
Tantalum Monocarbide (TaC)
41.3-91.3x106
room temp.
Titanium Monocarbide (TiC)
63.715x106
room temp. 1000˚C
(hot pressed)
6
45-55x106 Trichromium Dicarbide (Cr3C2)
54.1x106
Tungsten Monocarbide (WC)
96.91-103.5x106
Zirconium Monocarbide (ZrC)
28.3-69.6x106
room temp. room temp.
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991)
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763
8.20 Mechanical Page 764 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 223. YOUNG’S MODULUS OF (SHEET 3 OF 7) Class
Ceramic
Nitrides
Aluminum Nitride (AlN)
Boron Nitride (BN) parallel to c axis
parallel to a axis
CERAMICS
Young’s Modulus (psi)
Temperature
50x106 46x106
25˚C 1000˚C
40x106
1400˚C
4.91x106 3.47x106
23˚C 300˚C
0.51x106
700˚C
12.46x106
23˚C
8.79x106
300˚C
1.54x106
700˚C 1000˚C
1.65x106 Titanium Mononitride (TiN)
11.47-36.3x106
Trisilicon tetranitride (Si3N4)
Oxides
(hot pressed)
36.25-47.13x106
(sintered)
28.28-45.68x106
(reaction sintered)
14.5-31.9x106
20˚C 20˚C
(hot pressed)
25.38-36.25x10
(reaction sintered)
17.4-29.0x106
20˚C 1400˚C 1400˚C
Aluminum Oxide (Al2O3)
50-59.3x106
room temp.
50-57.275 x106
500˚C 800˚C 1000˚C
6
51.2 x106 45.5-50 x106 To convert from psi to MPa, multiply by 145.
Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991)
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CRC Handbook of Materials Science & Engineering
8.20 Mechanical Page 765 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 223. YOUNG’S MODULUS OF (SHEET 4 OF 7)
CERAMICS
Class
Ceramic
Young’s Modulus (psi)
Temperature
Oxides (Con’t)
Aluminum Oxide (Al2O3) (Con’t)
39.8-53.65 x106
1200˚C
32 x106
1250˚C 1400˚C 1500˚C
32.7 x106 25.6 x106 Beryllium Oxide (BeO)
42.8-45.5x106 40 x106 33 x106 20 x106
Cerium Dioxide (CeO2)
24.9x106
Dichromium Trioxide (Cr2O3)
>14.9x106
Hafnium Dioxide (HfO2)
8.2x106
Magnesium Oxide (MgO)
30.5-36.3x106
4 x106
room temp. 600˚C 1000˚C 1200˚C 1300˚C
42.74x106
room temp.
29.5 x106 21 x106 10 x106
(ρ = 3.506 g/cm3)
room temp. 800˚C 1000˚C 1145˚C
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991)
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765
8.20 Mechanical Page 766 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 223. YOUNG’S MODULUS OF (SHEET 5 OF 7)
CERAMICS
Class
Ceramic
Young’s Modulus (psi)
Temperature
Oxides (Con’t)
Thorium Dioxide (ThO2)
17.9-34.87x106
room temp.
18-18.5x106
800˚C 1000˚C 1200˚C
17.1x106 12.8x106 Titanium Oxide (TiO2)
41x106
Uranium Dioxide (UO2)
21x106 25x106
(ρ=10.37 g/cm3)
27.98x106
0-1000˚C 20˚C room temp.
Zirconium Oxide (ZrO2) (partially stabilized)
29.7x106
(fully stabilized)
14.1-30.0x106
(plasma sprayed)
6.96x106 24.8-27x106 36x106 2x106 18.9x106 18.5-25x106 3.05x106 17.1-18.0x106 14.2x106 12.8x106
room temp. room temp. room temp. room temp. 20˚C 500˚C 800˚C 1000˚C 1100˚C 1200˚C 1400˚C 1500˚C
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991)
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CRC Handbook of Materials Science & Engineering
8.20 Mechanical Page 767 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 223. YOUNG’S MODULUS OF (SHEET 6 OF 7)
CERAMICS
Young’s Modulus (psi)
Temperature
(stabilized, ρ=5.634 g/cm3)
19.96x106
room temp.
Cordierite (2MgO 2Al2O3 5SiO2)
20.16x106
(glass)
13.92x106
Class
Ceramic
Oxides (Con’t)
Uranium Dioxide (UO2) (Con’t)
Mullite (3Al2O3 2SiO2) (ρ=2.779 g/cm3)
20.75x106
(ρ=2.77 g/cm3)
18.42x106
(ρ=2.77 g/cm3)
18.89x106
(ρ=2.77 g/cm3)
14.79x106
(ρ=2.77 g/cm3)
4.00x106
(full density)
33.35x106
Spinel (Al2O3 MgO)
34.5x106 34.4x106 34.5x106 34x106 32.9x106 30.4x106 25.0x106 20.1x106
(ρ=3.510 g/cm3)
38.23x106
room temp. 25˚C 400˚C 800˚C 1200˚C room temp. room temp. 200˚C 400˚C 600˚C 800˚C 1000˚C 1200˚C 1300˚C room temp.
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991)
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Shackelford & Alexander
767
8.20 Mechanical Page 768 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 223. YOUNG’S MODULUS OF (SHEET 7 OF 7)
CERAMICS
Class
Ceramic
Young’s Modulus (psi)
Temperature
Oxides (Con’t)
Zircon (SiO2 ZrO2)
24x106
room temp.
Silicide
Molybdenum Disilicide (MoSi2)
39.3-56.36x106
room temp.
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991)
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CRC Handbook of Materials Science & Engineering
8.20 Mechanical Page 769 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 224. YOUNG’S MODULUS OF (SHEET 1 OF 2) Class
GLASS
Young’s Modulus (GPa)
Temperature
72.76–74.15 79.87 80.80
20˚C 998˚C (annealing point) 1096˚C (straining point)
64.4 62.0
room temp. room temp.
(25% mol Na2O)
56.9 61.4 53.9
–196˚C room temp. 200–250˚C
(30% mol Na2O)
60.5
room temp.
(33% mol Na2O) (33% mol Na2O)
54.9 60.3 51.0
–196˚C room temp. 200–250˚C
(35% mol Na2O)
60.2
room temp.
(40% mol Na2O) (40% mol Na2O)
51.9 46.1
–196˚C 200–250˚C
SiO2–PbO glass (24.6% mol PbO) (30.0% mol PbO) (35.7% mol PbO)
47.1 50.1 46.3
(38.4% mol PbO) (45.0% mol PbO) (50.0% mol PbO)
52.8 51.7 44.1
(55.0% mol PbO) (60.0% mol PbO) (65.0% mol PbO)
49.3 43.6 41.2
Glass
SiO2 glass SiO2–Na2O glass (15% mol Na2O) (20% mol Na2O) (25% mol Na2O) (25% mol Na2O)
(33% mol Na2O)
Source: data compiled by J.S. Park from O. V. Mazurin, M. V. Streltsina and T. P. Shvaiko– Shvaikovskaya, Handbook of Glass Data, Part A and Part B, Elsevier, New York, 1983.
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769
8.20 Mechanical Page 770 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 224. YOUNG’S MODULUS OF (SHEET 2 OF 2) Class
Glass
SiO2–B2O3 glass
(60% mol B2O3) (65% mol B2O3) (70% mol B2O3) (75% mol B2O3) (80% mol B2O3) (85% mol B2O3)
Temperature
23.3 22.5 23.5 24.1 22.8
(95% mol B2O3)
21.2 20.9 21.2
B2O3 glass
17.2–17.7
room temp.
31.4 43.2
15˚C 15˚C
53.7 59.4 57.1
15˚C 15˚C 15˚C
(90% mol B2O3)
B2O3 glass
Young’s Modulus (GPa)
GLASS
B2O3–Na2O glass (10% mol Na2O) (20% mol Na2O) (25% mol Na2O) (33.3% mol Na2O) (37% mol Na2O)
Source: data compiled by J.S. Park from O. V. Mazurin, M. V. Streltsina and T. P. Shvaiko– Shvaikovskaya, Handbook of Glass Data, Part A and Part B, Elsevier, New York, 1983.
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CRC Handbook of Materials Science & Engineering
8.20 Mechanical Page 771 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 225. ELASTIC
MODULUS OF WROUGHT STAINLESS STEELS * (SHEET 1 OF 2)
Type
UNS Designation
Elastic Modulus (GPa)
201 205 301 302
S20100 S20500 S30100 S30200
197 197 193 193
302B 303 304 S30430
S30215 S30300 S30400 S30430
193 193 193 193
304N 305 308 309
S30451 S30500 S30800 S30900
196 193 193 200
310 314 316 316N
S31000 S31400 S31600 S31651
200 200 193 196
317 317L 321 330
S31700 S31703 S32100 N08330
193 200 193 196
347 384 405 410
S34700 S38400 S40500 S41000
193 193 200 200
414 416 420 429
S41400 S41600 S42000 S42900
200 200 200 200
Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p360, (1993).
©2001 CRC Press LLC Shackelford & Alexander
771
8.20 Mechanical Page 772 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 225. ELASTIC
MODULUS OF WROUGHT STAINLESS STEELS * (SHEET 2 OF 2)
Type
UNS Designation
Elastic Modulus (GPa)
430 430F 431 434 436 440A
S43000 S43020 S43100 S43400 S43600 S44002
200 200 200 200 200 200
440C 444 446 PH 13–8 Mo
S44004 S44400 S44600 S13800
200 200 200 203
15–5 PH 17–4 PH 17–7 PH
S15500 S17400 S17700
196 196 204
Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p360, (1993). *
Annealed Condition.
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CRC Handbook of Materials Science & Engineering
8.20 Mechanical Page 773 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 226. MODULUS OF
ELASTICITY OF WROUGHT TITANIUM ALLOYS
Class
Metal or Alloy
Modulus of Elasticity (GPa)
Commercially Pure
99.5 Ti 99.2 Ti 99.1 Ti
102.7 102.7 103.4
99.0Ti 99.2 Ti–0.2Pd
104.1 102.7
Alpha Alloys
Ti-5Al-2.5Sn Ti-5Al-2.5Sn (low O2)
110.3 110.3
Near Alpha Alloys
Ti-8Al-1Mo-1V Ti-11Sn-1Mo-2.25Al-5.0Zr-1Mo-0.2Si Ti-6Al-2Sn-4Zr-2Mo
124.1 113.8 113.8
Ti-5Al-5Sn-2Zr-2Mo-0.25Si Ti-6Al-2Nb-1Ta-1Mo
113.8 113.8
Ti-8Mn Ti-3Al-2.5V Ti-6Al-4V Ti-6Al-4V (low O2)
113.1 106.9 113.8 113.8
Ti-6Al-6V-2Sn Ti-7Al-4Mo Ti-6Al-2Sn-4Zr-6Mo
110.3 113.8 113.8
Ti-6Al-2Sn-2Zr-2Mo-2Cr-0.25Si Ti-10V-2Fe-3Al
122.0 111.7
Ti-13V-11Cr-3Al Ti-8Mo-8V-2Fe-3Al Ti-3Al-8V-6Cr-4Mo-4Zr Ti-11.5Mo-6Zr-4.5Sn
101.4 106.9 105.5 103.4
Alpha-Beta Alloys
Beta Alloys
Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p511, (1993).
©2001 CRC Press LLC Shackelford & Alexander
773
8.21 Mechanical L Page 774 Wednesday, December 31, 1969 17:00
Table 227. MODULUS OF
ELASTICITY IN TENSION FOR POLYMERS (SHEET 1 OF 6)
Class
Polymer
Modulus of Elasticity in Tension, (ASTM D638) (l05 psi)
ABS Resins; Molded, Extruded
Medium impact High impact Very high impact Low temperature impact Heat resistant
3.3—4.0 2.6—3.2 2.0—3.1 2.0—3.1 3.5—4.2
Acrylics; Cast, Molded, Extruded
Cast Resin Sheets, Rods: General purpose, type I General purpose, type II Moldings: Grades 5, 6, 8 High impact grade
3.5—5.0 2.3—3.3
Chlorinated polyether Chlorinated polyvinyl chloride
1.5 3.7
Chlorinated Polymers
3.5—4.5 4.0—5.0
To convert psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.21 Mechanical L Page 775 Wednesday, December 31, 1969 17:00
Table 227. MODULUS OF
ELASTICITY IN TENSION FOR POLYMERS (SHEET 2 OF 6)
Class
Polymer
Modulus of Elasticity in Tension, (ASTM D638) (l05 psi)
Polycarbonates
Polycarbonate Polycarbonate (40% glass fiber reinforced)
3.45 17
Diallyl Phthalates; Molded
Orlon filled Asbestos filled
6 12
Fluorocarbons; Molded,Extruded
Polytrifluoro chloroethylene (PTFCE) Polytetrafluoroethylene (PTFE) Ceramic reinforced (PTFE) Fluorinated ethylene propylene(FEP) Polyvinylidene— fluoride (PVDF)
1.9—3.0 0.38—0.65 1.5—2.0 0.5—0.7 1.7—2
Epoxies; Cast, Molded, Reinforced
Standard epoxies (diglycidyl ethers of bisphenol A) Cast rigid Cast flexible
4.5 0.5—2.5
To convert psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.21 Mechanical L Page 776 Wednesday, December 31, 1969 17:00
Table 227. MODULUS OF
ELASTICITY IN TENSION FOR POLYMERS (SHEET 3 OF 6)
Class
Polymer
Modulus of Elasticity in Tension, (ASTM D638) (l05 psi)
Epoxies; Cast, Molded, Reinforced (Con’t)
Molded: General purpose glass cloth laminate High strength laminate Filament wound composite
33—36 57—58 72—64
Melamines; Molded
High performance resins (cycloaliphatic diepoxides) Cast, rigid Molded Glass cloth laminate Epoxy novolacs Cast, rigid Glass cloth laminate
4.8—5.0 27.5
Unfilled Cellulose electrical
10—11
4—5 32—33
To convert psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.21 Mechanical L Page 777 Wednesday, December 31, 1969 17:00
Table 227. MODULUS OF
ELASTICITY IN TENSION FOR POLYMERS (SHEET 4 OF 6)
Class
Polymer
Modulus of Elasticity in Tension, (ASTM D638) (l05 psi)
Phenolics; Molded
Type and filler General: woodflour and flock Shock: paper, flock, or pulp High shock: chopped fabric or cord Very high shock: glass fiber
8—13 8—12 9—14 30—33
Arc resistant—mineral Rubber phenolic—woodflour or flock Rubber phenolic—chopped fabric Rubber phenolic—asbestos
10—30 4—6 3.5—6 5—9
Cast polyyester Rigid Flexible
1.5—6.5 0.001—0.10
Polyesters: Thermosets
To convert psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.21 Mechanical L Page 778 Wednesday, December 31, 1969 17:00
Table 227. MODULUS OF
ELASTICITY IN TENSION FOR POLYMERS (SHEET 5 OF 6)
Class
Polymer
Modulus of Elasticity in Tension, (ASTM D638) (l05 psi)
Polyesters: Thermosets (Con’t)
Reinforced polyester moldings High strength (glass fibers) Heat and chemical resistsnt (asbestos) Sheet molding compounds, general purpose
16—20 12—15 15—20
Type I—lower density (0.910—0.925) Melt index 0.3—3.6 Melt index 6—26
0.21—0.27 0.20—0.24
Polystyrenes General purpose Medium impact High impact Glass fiber -30% reinforced
D638 4.6—5.0 2.6—4.7 1.50—3.80 12.1
Polyethylenes; Molded, Extruded
Polystyrenes; Molded
To convert psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.21 Mechanical L Page 779 Wednesday, December 31, 1969 17:00
Table 227. MODULUS OF
ELASTICITY IN TENSION FOR POLYMERS (SHEET 6 OF 6)
Class
Polymer
Modulus of Elasticity in Tension, (ASTM D638) (l05 psi)
SAN
Styrene acrylonitrile (SAN) Glass fiber (30%) reinforced SAN
4.0—5.2 17.5
Polyvinyl Chloride And Copolymers;
ASTM D412 Molded, Extruded Nonrigid—general Nonrigid—electrical Rigid—normal impact Vinylidene chloride
0.004—0.03 0.01—0.03 3 5—4.0 0.7—2.0
Woven glass fabric/ silicone laminate
ASTM D651 28
Alpha—cellulose filled (ASTM Type l) Woodflour filled
13—16 11—14
Silicones; Molded, Laminated
Ureas; Molded
To convert psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.21 Mechanical L Page 780 Wednesday, December 31, 1969 17:00
Table 228. MODULUS OF
ELASTICITY OF 55MSI GRAPHITE /6061 ALUMINUM COMPOSITES Material
Reinforcement content (vol % )
Fiber orientation
Modulus of Elasticity (GPa)
55MSI graphite/6061 aluminum composites 55MSI graphite/6061 aluminum composites
34 34
0° 90°
182.2±6.6 33
Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p148,(1994).
©2001 CRC Press LLC
8.21 Mechanical L Page 781 Wednesday, December 31, 1969 17:00
Table 229. MODULUS OF
ELASTICITY OF GRAPHITE /MAGNESIUM CASTINGS *
Fiber Type
Fiber content
Fiber orientation
P75
40% plus 9% 40%
±16° 90° ± 16°
40% 30% 10% 20% 20%
0° 0° plus 90° 0° plus 90°
P100 P55
Modulus of Elasticity, 0° (GPa)
Modulus of Elasticity,90° (GPa)
179
86
Hollow cylinder
Filament wound Filament wound Filament wound
228
30
Plate Plate
Prepreg Prepreg
159 83
21 34
Plate
Prepreg
90
90
Casting
Hollow cylinder
Fiber Preform Method
Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p148,(1994). *
Pitch-base fibers
©2001 CRC Press LLC
8.22 Mechanical Page 782 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 230. MODULUS OF
ELASTICITY OF GRAPHITE /ALUMINUM COMPOSITES
Thornel Fiber
Longitudinal Modulus of Elasticity (GPa)
Transverse Modulus of Elasticity (GPa)
P55 P75 P100
207 to 221 276 to 296 379 to 414
28 to 41 28 to 41 28 to 41
Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p148,(1994).
Table 231. MODULUS OF
ELASTICITY OF GRAPHITE FIBER REINFORCED METALS Composite
Fiber content (vol%)
Modulus of Elasticity (106psi)
Graphite(a)/lead Graphite(b)/lead Graphite(a)/zinc Graphite(a)/magnesium
41 35 35 42
29.0 17.4 16.9 26.6
(a) Thornel 75 fiber (b) Courtaulds HM fiber To convert from psi to MPa, multiply by 145. Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p148,(1994).
©2001 CRC Press LLC
782
CRC Handbook of Materials Science & Engineering
8.22 Mechanical Page 783 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 232. MODULUS OF
ELASTICITY OF SIC-WHISKER –REINFORCED ALUMINUM ALLOY Modulus of Elasticity Fiber Content (vol %)
(GPa)
Standard Deviation
Range of Measurement
0 12 16 20
71.9 95.3 90.0 111.0
4.5 1.6 3.7 5.0
13 6 9 13
Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p150,(1994).
©2001 CRC Press LLC
Shackelford & Alexander
783
8.22 Mechanical Page 784 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 233. MODULUS OF
ELASTICITY OF POLYCRYSTALLINE –ALUMINA–REINFORCED ALUMINUM ALLOY Modulus of Elasticity Fiber Content (vol %)
(GPa)
Standard Deviation
Range of Measurement
0 5 12 20
71.9 78.4 83.0 95.2
4.5 2.3 7.8 2.7
13 6 21 7
Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p154,(1994).
Table 234. MODULUS OF
ELASTICITY OF BORON/ALUMINUM COMPOSITES *
Matrix
Fiber Orientation
Modulus of Elasticity (GPa)
Al-6061
0° 90°
207 138
Al-2024
0° 90°
207 145
Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p157,(1994). *
These samples contain 48% Avco (142 µm) boron. Longitudinal tensile specimens are 152 mm by 7.9 mm by 6 ply. Transverse tensile bars are 152 mm by 12.7 mm by 6 ply.
©2001 CRC Press LLC
784
CRC Handbook of Materials Science & Engineering
8.22 Mechanical Page 785 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 235. COMPRESSION
MODULUS OF TREATED DUCTILE IRONS
Treatment
Compression Modulus (MPa)
60-40-18 65-45-12 80-55-06 120 90-02
164 163 165 164
Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, p169-170, (1984).
Table 236. MODULUS OF
ELASTICITY IN COMPRESSION FOR POLYMERS
Polymer
Modulus of Elasticity in Compression, (ASTM D638) (l05 psi)
Fluorocarbons; Molded,Extruded Polytrifluoro chloroethylene (PTFCE) Polytetrafluoroethylene (PTFE) Ceramic reinforced (PTFE) Fluorinated ethylene propylene(FEP) Polyvinylidene— fluoride (PVDF)
1.8 0 70—0.90 1.5—2.0 0.6—0.8 1.7—2
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
Shackelford & Alexander
785
8.22 Mechanical Page 786 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 237. BULK
Glass
MODULUS OF GLASS Bulk Modulus (GPa)
Temperature
SiO2 glass SiO2-Na2O glass (15% mol Na2O) (20% mol Na2O) (25% mol Na2O)
31.01-37.62 33.8 34.8 36.5
room temp. room temp. room temp.
(30% mol Na2O) (35% mol Na2O)
38.2 40.1 39.8
room temp. room temp. room temp.
SiO2-PbO glass (24.6% mol PbO) (30.0% mol PbO) (35.7% mol PbO)
33.9 25.6 31.1
(38.4% mol PbO) (45.0% mol PbO) (50.0% mol PbO)
25.1 30.6 30.5
(55.0% mol PbO) (60.0% mol PbO) (65.0% mol PbO)
29.5 33.1 31.6
(33% mol Na2O)
B2O3-Na2O glass (10% mol Na2O) (20% mol Na2O) (25% mol Na2O) (33.3% mol Na2O) (37% mol Na2O)
23.2 33.6
15˚C 15˚C
39.2 44.4 42.1
15˚C 15˚C 15˚C
Source: data compiled by J.S. Park from O. V. Mazurin, M. V. Streltsina and T. P. ShvaikoShvaikovskaya, Handbook of Glass Data, Part A and Part B, Elsevier, New York, 1983
©2001 CRC Press LLC
786
CRC Handbook of Materials Science & Engineering
8.22 Mechanical Page 787 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 238. SHEAR MODULUS OF (SHEET 1 OF 2)
GLASS
Shear Modulus (GPa)
Temperature
SiO2 glass
31.38 33.57 34.15
20˚C 998˚C (annealing point) 1096˚C (straining point)
(5% mol Na2O)
27.2 27.4 27.6 27.2
–100˚C 0˚C 80˚C 160˚C
26.9 27.2
–100—160˚C room temp.
25.8 25.0 24.8 24.2
–100˚C 0˚C 80˚C 160˚C
25.8 25.2
room temp. room temp.
24.5 24.2 24.1
room temp. room temp. room temp.
Class
Glass
SiO2 glass
SiO2–Na2O glass
(5% mol Na2O) (5% mol Na2O) (5% mol Na2O) (7.5% mol Na2O) (15% mol Na2O) (18% mol Na2O) (18% mol Na2O) (18% mol Na2O) (18% mol Na2O) (20% mol Na2O) (25% mol Na2O) (30% mol Na2O) (33% mol Na2O) (35% mol Na2O)
Source: data compiled by J.S. Park from O. V. Mazurin, M. V. Streltsina and T. P. Shvaiko– Shvaikovskaya, Handbook of Glass Data, Part A and Part B, Elsevier, New York, 1983.
©2001 CRC Press LLC Shackelford & Alexander
787
8.22 Mechanical Page 788 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 238. SHEAR MODULUS OF (SHEET 2 OF 2) Class
Glass
Shear Modulus (GPa)
SiO2–PbO glass
(24.6% mol PbO) (30.0% mol PbO) (35.7% mol PbO)
20.4 21.4 18.5
(38.4% mol PbO) (45.0% mol PbO) (50.0% mol PbO)
23.0 21.2 17.5
(55.0% mol PbO) (60.0% mol PbO) (65.0% mol PbO)
20.2 17.0 16.1
B2O3 glass
B2O3–Na2O glass
(10% mol Na2O) (20% mol Na2O) (25% mol Na2O) (33.3% mol Na2O) (37% mol Na2O)
GLASS Temperature
6.55 6.29 6.07 5.78
room temp. 250˚C 260˚C 270˚C
5.49 5.15 4.75
280˚C 290˚C 300˚C
12.3 16.8
15˚C 15˚C
21.1 23.2 22.4
15˚C 15˚C 15˚C
Source: data compiled by J.S. Park from O. V. Mazurin, M. V. Streltsina and T. P. Shvaiko– Shvaikovskaya, Handbook of Glass Data, Part A and Part B, Elsevier, New York, 1983.
©2001 CRC Press LLC
788
CRC Handbook of Materials Science & Engineering
8.22 Mechanical Page 789 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 239. TORSIONAL
MODULUS OF GRAY CAST IRONS
ASTM Class
Torsional Modulus (GPa)
20 25 30
27 to 39 32 to 41 36 to 45
35 40 50 60
40 to 48 44 to 54 50 to 55 54 to 59
Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, p166-167, (1984).
Table 240. TORSION
MODULUS OF TREATED DUCTILE IRONS
Treatment
Torsion Modulus (MPa)
60-40-18 65-45-12 80-55-06 120 90-02
63 64 62 63.4
Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, p169-170, (1984).
©2001 CRC Press LLC
Shackelford & Alexander
789
8.23 Mechanical L Page 790 Wednesday, December 31, 1969 17:00
Table 241. MODULUS OF
FOR
ELASTICITY IN FLEXURE
POLYMERS
(SHEET 1 OF 13)
Polymer Class
Polymer
Modulus of Elasticity in Flexure (ASTM D790) (105 psi)
ABS Resins; Molded, Extruded
Medium impact High impact Very high impact
3.5—4.0 2.5—3.2 2.0—3.2
Low temperature impact Heat resistant
2.0—3.2 3.5—4.2
Cast Resin Sheets, Rods: General purpose, type I General purpose, type II
3.5—4.5 4.0—5.0
Moldings: Grades 5, 6, 8 High impact grade
3.5—5.0 2.7—3.6
Acrylics; Cast, Molded, Extruded
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.23 Mechanical L Page 791 Wednesday, December 31, 1969 17:00
Table 241. MODULUS OF
FOR
ELASTICITY IN FLEXURE
POLYMERS
(SHEET 2 OF 13)
Polymer Class
Polymer
Modulus of Elasticity in Flexure (ASTM D790) (105 psi)
Thermoset Carbonate
Allyl diglycol carbonate
2.5—3.3
Alkyds; Molded
Rope (general purpose) Granular (high speed molding) Glass reinforced (heavy duty parts)
22—27 22—27 22—28
Cellulose Acetate; Molded, Extruded
ASTM Grade: H4—1 H2—1
(ASTM D747) 2.0—2.55 1.50—2.35
MH—1, MH—2 MS—1, MS—2 S2—1
1.50—2.15 1.25—1.90 1.05—1.65
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.23 Mechanical L Page 792 Wednesday, December 31, 1969 17:00
Table 241. MODULUS OF
FOR
Polymer Class
ELASTICITY IN FLEXURE
POLYMERS
(SHEET 3 OF 13)
Polymer
Cellulose Acetate Butyrate; Molded, Extruded
Modulus of Elasticity in Flexure (ASTM D790) (105 psi)
(ASTM D747) ASTM Grade: H4 MH S2
1.8 1.20—1.40 0.70—0.90
ASTM Grade: 1 3 6
1.7—1.8 1.45—1.55 1.1
Chlorinated Polymers
Chlorinated polyether Chlorinated polyvinyl chloride
1.3 (0.1% offset) 3.85
Polycarbonates
Polycarbonate Polycarbonate (40% glass fiber reinforced)
3.4 12
Cellusose Acetate Propionate; Molded, Extruded
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.23 Mechanical L Page 793 Wednesday, December 31, 1969 17:00
Table 241. MODULUS OF
FOR
ELASTICITY IN FLEXURE
POLYMERS
(SHEET 4 OF 13)
Polymer Class
Polymer
Modulus of Elasticity in Flexure (ASTM D790) (105 psi)
Fluorocarbons; Molded,Extruded
Polytrifluoro chloroethylene (PTFCE) Polytetrafluoroethylene (PTFE) Ceramic reinforced (PTFE)
2.0—2.5 0.6—1.1 4.64
Fluorinated ethylene propylene(FEP) Polyvinylidene— fluoride (PVDF)
0.8 1.75—2.0
Standard epoxies (diglycidyl ethers of bisphenol A) Cast rigid Cast flexible Molded
4.5—5.4 0.36—3.9 15—25
General purpose glass cloth laminate High strength laminate Filament wound composite
36—39 53—55 69—75
Epoxies; Cast, Molded, Reinforced
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.23 Mechanical L Page 794 Wednesday, December 31, 1969 17:00
Table 241. MODULUS OF
FOR
ELASTICITY IN FLEXURE
POLYMERS
(SHEET 5 OF 13) Modulus of Elasticity in Flexure (ASTM D790) (105 psi)
Polymer Class
Polymer
Epoxies—Molded, Extruded
High performance resins (cycloaliphatic diepoxides) Cast, rigid Glass cloth laminate Epoxy novolacs Cast, rigid Glass cloth laminate
4.4—4.8 32—35
Filler & type Unfilled Cellulose electrical Glass fiber
10—13 10—13 24
Melamines; Molded
4—5 28—31
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.23 Mechanical L Page 795 Wednesday, December 31, 1969 17:00
Table 241. MODULUS OF
FOR
ELASTICITY IN FLEXURE
POLYMERS
(SHEET 6 OF 13)
Polymer Class
Polymer
Modulus of Elasticity in Flexure (ASTM D790) (105 psi)
Nylons; Molded, Extruded
Type 6 General purpose Glass fiber (30%) reinforced Cast Flexible copolymers
1.4—3.9 1.0—1.4 5.05 0.92—3.2
Type 8 Type 11
0.4 1.51
6/6 Nylon General purpose molding Glass fiber reinforced Glass fiber Molybdenum disulfide filled General purpose extrusion
1.75–4.5 10—18 11—13 1.75—4.1
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.23 Mechanical L Page 796 Wednesday, December 31, 1969 17:00
Table 241. MODULUS OF
FOR
ELASTICITY IN FLEXURE
POLYMERS
(SHEET 7 OF 13)
Polymer Class
Polymer
Modulus of Elasticity in Flexure (ASTM D790) (105 psi)
Nylons; Molded, Extruded (Con’t)
6/10 Nylon General purpose Glass fiber (30%) reinforced
1.6–2.8 8.5
Type and filler General: woodflour and flock Shock: paper, flock, or pulp High shock: chopped fabric or cord Very high shock: glass fiber
8—12 8—12 9—13 30—33
Arc resistant—mineral Rubber phenolic—woodflour or flock Rubber phenolic—chopped fabric Rubber phenolic—asbestos
10—30 4—6 3.5 5
ABS–Polycarbonate Alloy
4
Phenolics; Molded
ABS–Polycarbonate Alloy To convert from psi to MPa, multiply by 145.
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.23 Mechanical L Page 797 Wednesday, December 31, 1969 17:00
Table 241. MODULUS OF
FOR
ELASTICITY IN FLEXURE
POLYMERS
(SHEET 8 OF 13)
Polymer Class
Polymer
Modulus of Elasticity in Flexure (ASTM D790) (105 psi)
PVC–Acrylic Alloy
PVC–acrylic sheet PVC–acrylic injection molded
4 3
Polymides
Unreinforced Unreinforced 2nd value Glass reinforced
7 5 38.4
Polyacetals
Homopolymer: Standard 20% glass reinforced 22% TFE reinforced
4.1 8.8 4
Copolymer: Standard 25% glass reinforced High flow
3.75 11 3.75
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.23 Mechanical L Page 798 Wednesday, December 31, 1969 17:00
Table 241. MODULUS OF
FOR
ELASTICITY IN FLEXURE
POLYMERS
(SHEET 9 OF 13)
Polymer Class
Polymer
Modulus of Elasticity in Flexure (ASTM D790) (105 psi)
Polyester; Thermoplastic
Injection Moldings: General purpose grade Glass reinforced grades Glass reinforced self extinguishing
3.4 12—15 12
General purpose grade Glass reinforced grade Asbestos—filled grade
33 87 90
Cast polyyester Rigid Flexible
1—9 0.001—0.39
Reinforced polyester moldings High strength (glass fibers) Sheet molding compounds, general purpose
15—25 15—18
Polyesters: Thermosets
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.23 Mechanical L Page 799 Wednesday, December 31, 1969 17:00
Table 241. MODULUS OF
FOR
ELASTICITY IN FLEXURE
POLYMERS
(SHEET 10 OF 13)
Polymer Class
Polymer
Modulus of Elasticity in Flexure (ASTM D790) (105 psi)
Phenylene Oxides
SE—100 SE—1 Glass fiber reinforced
3.6 3.6 7.4—10.4
Phenylene oxides (Noryl)
Standard Glass fiber reinforced
3.9 12, 15.5
Polyarylsulfone
4
General purpose High impact
1.7—2.5 1.0—2.0
Asbestos filled Glass reinforced Flame retardant
3.4—6.5 4—8.2 1.9—6.1
Polypropylene:
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.23 Mechanical L Page 800 Wednesday, December 31, 1969 17:00
Table 241. MODULUS OF
FOR
ELASTICITY IN FLEXURE
POLYMERS
(SHEET 11 OF 13)
Polymer Class
Polymer
Modulus of Elasticity in Flexure (ASTM D790) (105 psi)
Polyphenylene sulfide:
Standard 40% glass reinforced
5.5—6.0 17—22
Polyethylenes; Molded, Extruded
(ASTM D747) Type I—lower density (0.910—0.925) Melt index 0.3—3.6 Melt index 6—26 Melt index 200
0.13—0.27 0.12—0.3 0.1
Type II—medium density (0.926—0.940) Melt index 20 Melt index l.0—1.9
0.35—0.5 0.35—0.5
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.23 Mechanical L Page 801 Wednesday, December 31, 1969 17:00
Table 241. MODULUS OF
FOR
ELASTICITY IN FLEXURE
POLYMERS
(SHEET 12 OF 13)
Polymer Class
Polymer
Modulus of Elasticity in Flexure (ASTM D790) (105 psi)
Polyethylenes; Molded, Extruded (Con’t)
Type III—higher density (0.941—0.965) Melt index 0.2—0.9 Melt Melt index 0.l—12.0 Melt index 1.5—15 High molecular weight
1.3—1.5 0.9—0.25 1.5 0.75
Olefin Copolymers; Molded
Ethylene butene Propylene—ethylene Polyallomer
165 (psi) 140 (psi) 0.7—1.3
Polystyrenes; Molded
Polystyrenes: General purpose Medium impact High impact Glass fiber -30% reinforced
4—5 3.5—5.0 2.3—4.0 12
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.23 Mechanical L Page 802 Wednesday, December 31, 1969 17:00
Table 241. MODULUS OF
FOR
ELASTICITY IN FLEXURE
POLYMERS
(SHEET 13 OF 13)
Polymer Class
Polymer
Modulus of Elasticity in Flexure (ASTM D790) (105 psi)
Styrene acrylonitrile (SAN):
Glass fiber (30%) reinforced SAN
14.5
Polyvinyl Chloride And Copolymers; Molded, Extruded
Rigid—normal impact
3.8—5.4
Silicones; Molded, Laminated
Fibrous (glass) reinforced silicones Granular (silica) reinforced silicones Woven glass fabric/ silicone laminate
25 14—17 26—32
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
8.24 Mechanical Page 803 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 242. FLEXURAL
MODULUS OF FIBERGLASS REINFORCED PLASTICS Flexural modulus (105 psi)
Class
Material
Glass fiber content (wt%)
Glass fiber reinforced thermosets
Sheet molding compound (SMC)
15 to 30
14 to 20
Bulk molding compound(BMC) Preform/mat(compression molded) Cold press molding–polyester
15 to 35 25 to 50 20 to 30
14 to 20 13 to 18 13 to 19
Spray–up–polyester Filament wound–epoxy Rod stock–polyester Molding compound–phenolic
30 to 50 30 to 80 40 to 80 5 to 25
10 to 12 50 to 70 40 to 60 30
Acetal
20 to 40
8 to 13
Nylon Polycarbonate Polyethylene
6 to 60 20 to 40 10 to 40
2 to 28 7.5 to 15 2.1 to 6
Polypropylene Polystyrene Polysulfone ABS(acrylonitrile butadiene styrene)
20 to 40 20 to 35 20 to 40 20 to 40
3.5 to 8.2 8 to 12 8 to 15 9.2 to 15
PVC (polyvinyl chloride) Polyphenylene oxide(modified) SAN (styrene acrylonitrile) Thermoplastic polyester
15 to 35 20 to 40 20 to 40 20 to 35
9 to 16 8 to 15 8.0 to 18 8.7 to 15
Glass–fiber–reinforced thermoplastics
To convert from psi to MPa, multiply by 145. Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p106, (1994).
©2001 CRC Press LLC
Shackelford & Alexander
803
8.24 Mechanical Page 804 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 243. FLEXURAL
MODULUS OF CARBON - AND GLASS REINFORCED ENGINEERING THERMOPLASTICS (SHEET 1 OF 2) Class
Resin Type
Composition
Flexural Modulus (GPa)
Amorphous
Acrylonitrile-butadiene-styrene(ABS)
30% glass fiber 30% carbon fiber
7.6 12.4
Nylon
30% glass fiber 30% carbon fiber
7.9 15.2
Polycarbonate
30% glass fiber 30% carbon fiber
8.3 13.1
Polyetherimide
30% glass fiber 30% carbon fiber
8.6 17.2
Polyphenylene oxide (PPO)
30% glass fiber 30% carbon fiber
9.0 11.7
Polysulfone
30% glass fiber 30% carbon fiber
8.3 14.5
Styrene-maleic-anhydride (SMA)
30% glass fiber
9.0
Thermoplastic polyurethane
30% glass fiber
1.3
Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p111–112, (1994).
©2001 CRC Press LLC
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CRC Handbook of Materials Science & Engineering
8.24 Mechanical Page 805 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 243. FLEXURAL
MODULUS OF CARBON - AND GLASS REINFORCED ENGINEERING THERMOPLASTICS (SHEET 2 OF 2) Class
Resin Type
Composition
Flexural Modulus (GPa)
Crystalline
Acetal
30% glass fiber 20% carbon fiber
9.7 9.3
Nylon 66
30% glass fiber 30% carbon fiber
9.0 20.0
Polybutylene telphthalate (PBT)
30% glass fiber 30% carbon fiber
9.7 15.9
Polythylene terephthalate (PET)
30% glass fiber
9.0
Polyphenylene sulfide (PPS)
30% glass fiber 30% carbon fiber
11.0 16.9
Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p111–112, (1994).
©2001 CRC Press LLC
Shackelford & Alexander
805
8.25 Mechanical L Page 806 Wednesday, December 31, 1969 17:00
Table 244. MODULUS OF RUPTURE FOR (SHEET 1 OF 10)
CERAMICS
Class
Ceramic
Modulus of Rupture (psi)
Borides
Titanium Diboride (TiB2)
19x103
(98% dense)
5.37x103
(6.0 µm grain size, ρ=4.46g/cm3)
6.2x103
(3.5 µm grain size, ρ=4.37g/cm3, 0.8wt% Ni)
5.7x103 11.0x103 6.29x103
(6.0 µm grain size, ρ=4.56g/cm3, 0.16wt% Ni) (12.0 µm grain size, ρ=4.66g/cm3, 9.6wt% Ni) Carbides
Temperature
Hafnium Monocarbide (HfC) (ρ = 11.9 g/cm3) (ρ = 11.9 g/cm3) (ρ = 11.9 g/cm3)
34.67x103 12.64x103 4.78x103
room temp. 2000 oC 2200 oC
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991).
©2001 CRC Press LLC
8.25 Mechanical L Page 807 Wednesday, December 31, 1969 17:00
Table 244. MODULUS OF RUPTURE FOR (SHEET 2 OF 10)
CERAMICS
Class
Ceramic
Modulus of Rupture (psi)
Temperature
Carbides (Con’t)
Silicon Carbide (SiC)
27x103
room temp.
25x103
1300 oC 1400 oC 1800 oC
11x103 15x103 (with 1 wt% Be addictive)
58x103
(with 1wt% B addictive)
42x103
(with 1wt% Al addictive)
136x103
Titanium Monocarbide (TiC) (ρ = 4.85 g/cm3) (ρ = 4.85 g/cm3)
32.67x103 13.6x103
room temp. 2000oC
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991).
©2001 CRC Press LLC
8.25 Mechanical L Page 808 Wednesday, December 31, 1969 17:00
Table 244. MODULUS OF RUPTURE FOR (SHEET 3 OF 10)
CERAMICS
Class
Ceramic
Modulus of Rupture (psi)
Temperature
Carbides (Con’t)
Tungsten Monocarbide (WC)
55.65-84x103
room temp.
Carbides (Con’t)
Zirconium Monocarbide (ZrC)
16.6-22.5x103
room temp.
8.3x103
1250 oC 1750 oC 2000 oC
5.14x103 2.5x103 Nitrides
Aluminum Nitride (AlN) (hot pressed)
38.5x103 27x103 18.1x103
25oC 1000oC 1400oC
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991).
©2001 CRC Press LLC
8.25 Mechanical L Page 809 Wednesday, December 31, 1969 17:00
Table 244. MODULUS OF RUPTURE FOR (SHEET 4 OF 10)
CERAMICS
Class
Ceramic
Modulus of Rupture (psi)
Nitrides (Con’t)
Boron Nitride (BN) parallel to c axis
7.28-13.2x103 7.03x103 1.90x103 1.08x103 1.25x103 1.50x103 2.45x103
Temperature
25 oC 300 oC 700 oC 1000 oC 1500 oC 1800 oC 2000 oC
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991).
©2001 CRC Press LLC
8.25 Mechanical L Page 810 Wednesday, December 31, 1969 17:00
Table 244. MODULUS OF RUPTURE FOR (SHEET 5 OF 10)
CERAMICS
Class
Ceramic
Modulus of Rupture (psi)
Nitrides (Con’t)
parallel to a axis
15.88x103 15.14x103 3.84x103 2.18x103
Titanium Mononitride (TiN)
34x103
(10wt% AlO and 10wt% AlN)
13.34x103
(30wt% AlO and 10wt% AlN)
23.93x103
(30wt% AlO and 30wt% AlN)
33.25x103
Temperature
25 oC 300 oC 700 oC 1000 oC
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991).
©2001 CRC Press LLC
8.25 Mechanical L Page 811 Wednesday, December 31, 1969 17:00
Table 244. MODULUS OF RUPTURE FOR (SHEET 6 OF 10) Class
Ceramic
Nitrides (Con’t)
Trisilicon Tetranitride (Si3N4)
CERAMICS Modulus of Rupture (psi)
(hot pressed)
65.3-159.5x103
(sintered)
39.9-121.8x103
(reaction sintered)
7.25-43.5x103
Temperature
20oC 20oC 20oC
Aluminum Oxide (Al2O3)
Oxides
(single crystal)
(80% dense, 3µm grain size) (80% dense, 3µm grain size) (80% dense, 3µm grain size) (80% dense, 3µm grain size)
131 x103 60 x103
room temp.
56x103 62x103 58x103 42x103
20 oC 600 oC 900 oC 1100 oC
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991).
©2001 CRC Press LLC
8.25 Mechanical L Page 812 Wednesday, December 31, 1969 17:00
Table 244. MODULUS OF RUPTURE FOR (SHEET 7 OF 10) Class
Ceramic
Oxides (Con’t)
Aluminum Oxide (Al2O3) (Con’t) (80% dense, 20µm grain size) (80% dense, 20µm grain size) (80% dense, 20µm grain size) (80% dense, 20µm grain size) (zirconia toughened alumina, 15 vol% ZrO2) (zirconia toughened alumina, 25 vol% ZrO2) (zirconia toughened alumina, 50 vol% ZrO2)
CERAMICS Modulus of Rupture (psi)
Temperature
30x103 28x103 31x103 30x103
20 oC 600 oC 900 oC 1100 oC
137x103 139x103 145x103
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991).
©2001 CRC Press LLC
8.25 Mechanical L Page 813 Wednesday, December 31, 1969 17:00
Table 244. MODULUS OF RUPTURE FOR (SHEET 8 OF 10)
CERAMICS
Class
Ceramic
Modulus of Rupture (psi)
Temperature
Oxides (Con’t)
Beryllium Oxide (BeO)
24-29 x103
room temp.
Dichromium Trioxide (Cr2O3)
>38x103
Hafnium Dioxide (HfO2)
10x103 10-14.9x103
Titanium Oxide (TiO2)
room temp.
Zirconium Oxide (ZrO2) (5-10 CaO stabilized)
20-35x103 3
(MgO stabilized)
30x10
(hot pressed yittria doped zirconia)
222x103
(sintered yittria doped zirconia)
148x103
room temp. room temp.
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991).
©2001 CRC Press LLC
8.25 Mechanical L Page 814 Wednesday, December 31, 1969 17:00
Table 244. MODULUS OF RUPTURE FOR (SHEET 9 OF 10) Class
Ceramic
Oxides (Con’t)
Cordierite (2MgO 2Al2O3 5SiO2) (ρ=2.51g/cm3) (ρ=2.3g/cm3) (ρ=2.1g/cm3) (ρ=1.8g/cm3) Mullite (3Al2O3 2SiO2) (ρ=2.77g/cm3) (ρ=2.77g/cm3) (ρ=2.77g/cm3) (ρ=2.77g/cm3)
CERAMICS Modulus of Rupture (psi)
Temperature
16x103 15x103 8x103 3.4x103
25oC 400oC 800oC 1200oC
6-27x103 8.5x103 13.5x103 16.7x103 11.5x103
25oC 25oC 400oC 800oC 1200oC
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991).
©2001 CRC Press LLC
8.25 Mechanical L Page 815 Wednesday, December 31, 1969 17:00
Table 244. MODULUS OF RUPTURE FOR (SHEET 10 OF 10)
CERAMICS Modulus of Rupture (psi)
Temperature
(ρ = 5.57 g/cm3)
18.57x103
room temp.
(sintered)
50.7x103
room temp.
(sintered)
67.25x103
(sintered)
86.00x103
980oC 1090oC
(hot pressed)
36-57x103
room temp.
(hot pressed)
3
72.00x10
(hot pressed)
55.00x103
Class
Ceramic
Silicide
Molybdenum Disilicide (MoSi2)
1090oC 1200oC
To convert from psi to MPa, multiply by 145. Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991).
©2001 CRC Press LLC
8.25 Mechanical L Page 816 Wednesday, December 31, 1969 17:00
Table 245. RUPTURE
STRENGTH OF REFRACTORY METAL ALLOYS (SHEET 1 OF 2)
Class
Alloy
Alloying Additions (%)
Form
Condition
Temperature (°F)
10-h rupture (ksi)
Niobium and Niobium Alloys
Pure Niobium
—
All
Recrystallized
2000
5.4
Nb–1Zr SCb291
1 Zr 10 Ta, 10 W
All Bar, Sheet
Recrystallized Recrystallized
2000 2000
14 9
C129 FS85 SU31
10 W, 10 Hf, 0.1 Y 28 Ta, 11 W, 0.8 Zr 17 W, 3.5 Hf, 0.12 C, 0.03 Si
Sheet Sheet Bar, Sheet
Recrystallized Recrystallized Special Thermal Processing
2400 2400 2400
15 12 22
Pure Molybdenum
—
All
Stress-relieved Annealed
1800
25
Low C Mo TZM
None 0.5 Ti, 0.08 Zr, 0.015 C
All All
Stress-relieved Annealed Stress-relieved Annealed
1800 2400
24 23
TZC Mo–5Re Mo–30W
1.0 Ti, 0.14 Zr, 0.02 to 0.08 C 5 Re 30 W
All All All
Stress-relieved Annealed Stress-relieved Annealed Stress-relieved Annealed
2400 3000 2000
28 1 20
Molybdenum and Molybdenum Alloys
To convert (ksi) to (MPa), multiply by 6.89 Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p106, (1994).
©2001 CRC Press LLC
8.25 Mechanical L Page 817 Wednesday, December 31, 1969 17:00
Table 245. RUPTURE
STRENGTH OF REFRACTORY METAL ALLOYS (SHEET 2 OF 2)
Class
Alloy
Alloying Additions (%)
Form
Condition
Temperature (°F)
10-h rupture (ksi)
Tantalum Alloys
Unalloyed TA–10W
None 10 W
All All
Recrystallized Recrystallized
2400 2400
2.5 20
Tungsten Alloys
Unalloyed
None
Stress-relieved Annealed
3000
6.8
W–2 ThO2
2 ThO2
Stress-relieved Annealed
3000
18
W–3 ThO2 W–4 ThO2
3 ThO2 4 ThO2
Bar, Sheet, Wire Bar, Sheet, Wire Bar, Wire Bar
Stress-relieved Annealed Stress-relieved Annealed
3000 3000
18 18
W–15 Mo W–50 Mo
15 Mo 50 Mo
Stress-relieved Annealed Stress-relieved Annealed
3000 3000
12 12
W–25 Re
25 Re
Bar, Wire Bar, Wire Bar, Sheet, Wire
Stress-relieved Annealed
3000
10
To convert (ksi) to (MPa), multiply by 6.89 Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p106, (1994).
©2001 CRC Press LLC
8.26 Mechanical Page 818 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 246. RUPTURE
STRENGTH OF SUPERALLOYS (SHEET 1 OF 3) Stress Rupture
Alloy *
Temperature (°C)
100 h (MPa)
1000 h (MPa)
Incoloy 800
650 760 870
220 115 45
145 69 33
Incoloy 801
650 730 815
250 145 62
— — —
Incoloy 802
650 760 870
240 145 97
170 105 62
Inconel 600
815 870
55 37
39 24
Inconel 601(a)
540 870 980
— 48 23
400 30 14
Inconel 617(b)
815 925 980
140 62 41
97 — —
Inconel 625(a)
650 815 870
440 130 72
370 93 48
Inconel 718(c)
540 595 650
— 860 690
951 760 585
Inconel 751(d)
815 870
200 120
125 69
Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p391, (1993).
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CRC Handbook of Materials Science & Engineering
8.26 Mechanical Page 819 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 246. RUPTURE
STRENGTH OF SUPERALLOYS (SHEET 2 OF 3) Stress Rupture
Alloy *
Temperature (°C)
100 h (MPa)
1000 h (MPa)
Inconel X–750(e)
540 870 925
— 83 58
827 45 21
N–155, bar(f)
650 730 870
360 195 97
295 150 66
N–155(g)
650
380
290
N–155, sheet(f)
980
39
20
Nimonic 75(h)
815 870 925 980
38 23 14 —
24 15 10 7.6
Nimonic 80A(j)
540 815 870
— 185 105
825 115 —
Nimonic 90(j)
815 870 925
240 150 69
155 69 —
Nimonic 105(k)
815 870
325 210
225 135
Nimonic 115(m)
815 870 925
425 315 205
315 205 130
Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p391, (1993).
©2001 CRC Press LLC Shackelford & Alexander
819
8.26 Mechanical Page 820 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 246. RUPTURE
STRENGTH OF SUPERALLOYS (SHEET 3 OF 3) Stress Rupture
Alloy *
Temperature (°C)
100 h (MPa)
1000 h (MPa)
Nimonic 263(n)
815 870 925
170 93 45
105 46 —
Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p391, (1993). *
(a) Solution treat 1150 °C. (b) Solution treat 1175 °C. (c) Heat treat to 980 °C plus 720 °C hold for 8 h, furnace cool to 620 °C hold for 8 h. (d) 730 °C hold for 2h. (e) Heat treat to 1150 °C plus 840 °C hold for 24h, plus 705 °C hold for 20h. (f) Solution treated and aged. (g) Stress-relieved forging. (h) Heat treat to 1050 °C hold for 1 h. (j) Heat treat to 1080 °C hold for 8 h, plus 700 °C hold for 16 h. (k) Heat treat to 1150 °C hold for 4 h, plus 1050 °C hold for 16 h, plus 850 °C hold for 16 h. (m) Heat treat to 1190 °C hold for 1.5 h, plus 1100 °C hold for 6 h. (n) Heat treat to 1150 °C hold for 2 h, water quench, plus 800 °C hold for 8 h.
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CRC Handbook of Materials Science & Engineering
8.26 Mechanical Page 821 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 247. MODULUS OF
RUPTURE FOR SI3N4 AND AL2O3COMPOSITES Modulus of Rupture (MPa)
Matrix
Dispersed Phase
RT
1000 °C
1200 °C
Si3N4+ 6 wt % Y2O3
None
110.9 ± 1.6
88.3 ± 3.5
49.2 ± 5.0
Si3N4+ 6 wt % Y2O3
TiC (Ti, W) C WC
80.6 ± 5.9 75.5 ± 3.2 89.1 ± 31.8
120.4 ± 12.2 86 ± 0 136.4 ± 1.6
64.4 ± 2.9 52.9 ± 0.5 55.7 ± 0.5
TaC HfC SiC
86.2 ± 7.3 86 ± 0.8 97.6 ± 8.5
124.5 ± 16.0 — 94.0 ± 4.9
43.2 ± 2.0 68.6 ± 0.5 52.3 ± 3.2
TiC
72.2 ± 13.0
69.4 ± 4.3
57.0 ± 4.1
Al2O3
Containing 30 Vol % of Metal Carbide Dispersoid (2 µm average particle diameter) Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p169,(1994).
©2001 CRC Press LLC Shackelford & Alexander
821
8.26 Mechanical Page 822 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 248. POISSON ' S
RATIO OF WROUGHT TITANIUM ALLOYS Class
Metal or Alloy
Poisson's Ratio
Commercially Pure
99.5 Ti 99.2 Ti 99.1 Ti
0.34 0.34 0.34
99.0Ti 99.2 Ti–0.2Pd
0.34 0.34
Near Alpha Alloys
Ti-8Al-1Mo-1V Ti-5Al-5Sn-2Zr-2Mo-0.25Si
0.32 0.326
Alpha-Beta Alloys
Ti-6Al-4V Ti-6Al-4V (low O2) Ti-6Al-2Sn-2Zr-2Mo-2Cr-0.25Si
0.342 0.342 0.327
Beta Alloys
Ti-13V-11Cr-3Al
0.304
Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p511, (1993).
©2001 CRC Press LLC
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CRC Handbook of Materials Science & Engineering
8.26 Mechanical Page 823 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 249. POISSON ’S RATIO FOR (SHEET 1 OF 2)
CERAMICS
Class
Ceramic
Poisson’s Ratio
Borides
Titanium Diboride (TiB2)
0.09-0.28
(6.0 µm grain size, ρ=4.46g/cm3)
(12.0 µm grain size, ρ=4.66g/cm3, 9.6wt% Ni)
0.10 0.12 0.11 0.15
Zirconium Diboride (ZrB2)
0.144
Boron Carbide (B4C) Hafnium Monocarbide (HfC)
0.207 0.166
(3.5 µm grain size, ρ=4.37g/cm3, 0.8wt% Ni) (6.0 µm grain size, ρ=4.56g/cm3, 0.16wt% Ni)
Carbides
Silicon Carbide (SiC) (ρ = 3.128 g/cm3)
0.183-0.192 at room temp.
Tantalum Monocarbide (TaC) Titanium Monocarbide (TiC) Tungsten Monocarbide (WC)
0.1719 -0.24 0.187-189 0.24
Zirconium Monocarbide (ZrC) (ρ = 6.118 g/cm3)
0.257
Nitrides
Trisilicon tetranitride (Si3N4) (presureless sintered)
0.24 0.22-0.27
Oxides
Aluminum Oxide (Al2O3) Beryllium Oxide (BeO) Cerium Dioxide (CeO2)
0.21-0.27 0.26-0.34
0.27-0.31
Magnesium Oxide (MgO) (ρ = 3.506 g/cm3)
0.163 at room temp.
Thorium Dioxide (ThO2) (ρ=9.722 g/cm3)
0.275
Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991)
©2001 CRC Press LLC Shackelford & Alexander
823
8.26 Mechanical Page 824 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 249. POISSON ’S RATIO FOR (SHEET 2 OF 2)
CERAMICS
Class
Ceramic
Poisson’s Ratio
Oxides (Con’t)
Titanium Oxide (TiO2)
0.28
Uranium Dioxide (UO2) (ρ=10.37 g/cm3)
0.302
Zirconium Oxide (ZrO2) (partially stabilized) (fully stabilized) (plasma sprayed)
0.324-0.337 at room temp. 0.23 0.23-0.32 0.25
Cordierite (2MgO 2Al2O3 5SiO2) (ρ=2.3g/cm3) (ρ=2.1g/cm3)
0.21 0.17
(glass)
0.26
Mullite (3Al2O3 2SiO2) (ρ=2.779 g/cm3)
0.238
Spinel (Al2O3 MgO)
Silicide
(ρ=3.510 g/cm3)
0.294
Molybdenum Disilicide (MoSi2)
0.158-0.172
Source: data compiled by J.S. Park from No. 1 Materials Index, Peter T.B. Shaffer, Plenum Press, New York, (1964); Smithells Metals Reference Book, Eric A. Brandes, ed., in association with Fulmer Research Institute Ltd. 6th ed. London, Butterworths, Boston, (1983); and Ceramic Source, American Ceramic Society (1986-1991)
©2001 CRC Press LLC
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CRC Handbook of Materials Science & Engineering
8.26 Mechanical Page 825 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 250. POISSON ’S RATIO OF (SHEET 1 OF 2) Class
Composition
Poisson’s Ratio
Temperature
0.166–0.177
room temp.
0.183 0.203 0.219
room temp. room temp. room temp.
(35% mol Na2O)
0.236 0.249 0.248
room temp. room temp. room temp.
(24.6% mol PbO) (30.0% mol PbO) (35.7% mol PbO)
0.249 0.174 0.252
(38.4% mol PbO) (45.0% mol PbO) (50.0% mol PbO)
0.150 0.219 0.259
(55.0% mol PbO) (60.0% mol PbO) (65.0% mol PbO)
0.222 0.281 0.283
SiO2 glass SiO2–Na2O glass
(15% mol Na2O) (20% mol Na2O) (25% mol Na2O) (30% mol Na2O) (33% mol Na2O)
SiO2–PbO glass
B2O3 glass
GLASS
0.288–0.309
room temp.
Source: data compiled by J.S. Park from O. V. Mazurin, M. V. Streltsina and T. P. Shvaiko– Shvaikovskaya, Handbook of Glass Data, Part A and Part B, Elsevier, New York, 1983
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8.26 Mechanical Page 826 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 250. POISSON ’S RATIO OF (SHEET 2 OF 2)
GLASS
Class
Composition
Poisson’s Ratio
Temperature
B2O3–Na2O glass
(5.5% mol Na2O)
0.279 0.2740 0.271
15˚C
(10% mol Na2O) (15.4% mol Na2O) (20% mol Na2O)
0.2860 0.272 0.2713 0.274
(22.8% mol Na2O) (25% mol Na2O) (29.8% mol Na2O) (33.3% mol Na2O)
15˚C 15˚C
0.2771 0.2739 0.292
(37% mol Na2O) (37.25% mol Na2O)
15˚C 15˚C
Source: data compiled by J.S. Park from O. V. Mazurin, M. V. Streltsina and T. P. Shvaiko– Shvaikovskaya, Handbook of Glass Data, Part A and Part B, Elsevier, New York, 1983
Table 251. POISSON ' S
RATIO OF SILICON CARBIDE SCS–2–AL Fiber orientation
No. of plies
Poisson's Ratio
0° 90° ± 45°
6, 8, 12 6, 12,40 8, 12, 40
0.268 0.124 0.395
Data from ASM Engineering Materials Reference Book, Second Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p149,(1994).
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Mechanical Properties
Table 252. COMPRESSION
POISSON ’S RATIO OF TREATED DUCTILE IRONS
Treatment
Compression Poisson’s Ratio
60-40-18 65-45-12 80-55-06 120 90-02
0.26 0.31 0.31 0.27
Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, p169-170, (1984).
Table 253. TORSION
POISSON ’S RATIO OF TREATED DUCTILE IRONS
Treatment
Torsion Poisson’s Ratio
60-40-18 65-45-12 80-55-06 120 90-02
0.29 0.29 0.31 0.28
Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, p169-170, (1984).
©2001 CRC Press LLC Shackelford & Alexander
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Mechanical Properties
Table 254. ELONGATION OF
TOOL STEELS Elongation (%)
Type
Condition
L2
Annealed Oil quenched from 855 •C and single tempered at: 205 •C 315 •C 425 •C 540 •C 650 •C
25
Annealed Oil quenched from 845 •C and single tempered at: 315 •C 425 •C 540 •C 650 •C
25
Annealed Oil quenched from 930 •C and single tempered at: 205 •C 315 •C 425 •C 540 •C 650 •C
24
Annealed Oil quenched from 870 •C and single tempered at: 205 •C 315 •C 425 •C 540 •C 650 •C
25
Annealed Fan cooled from 940 •C and single tempered at: 205 •C 315 •C 425 •C 540 •C 650 •C
25
L6
S1
S5
S7
5 10 12 15 25
4 8 12 20
4 5 9 12
5 7 9 10 15
7 9 10 10 14
Source: Data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, p241, (1984).
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Mechanical Properties
Table 255. ELONGATION OF
DUCTILE IRONS
Specification Number
Grade or Class
Elongation (%)
ASTM A395-76 ASME SA395
60-40-18
18
ASTM A476-70(d); SAE AMS5316
80-60-03
3
60-40-18 65-45-12
18 12
80-55-06 100-70-03 120-90-02
6 3 2
SAE J434c
D4018 D4512 D5506 D7003
18 12 6 3
MlL-I-24137(Ships)
Class A Class B Class C
15 7 20
ASTM A536-72, MIL-1-11466B(MR)
Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, p169, (1984).
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Mechanical Properties
Table 256. ELONGATION OF
Specification Number Ferritic ASTM A47, A338; ANSI G48.1; FED QQ-I-666c
MALLEABLE IRON CASTINGS Grade or Class
32510 35018
10 18 5
40010 45008 45006 50005
10 8 6 5
60004 70003 80002 90001
4 3 2 1
M3210 M4504(a) M5003(a)
10 4 3
M5503(b) M7002(b) M8501(b)
3 2 1
ASTM A197 Pearlitic and Martensitic ASTM A220; ANSI C48.2; MIL-I-11444B
Automotive ASTM A602; SAE J158
Elongation (%)
(a) Air quenched and tempered (b) Liquid quenched and tempered Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, p171, (1984).
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8.27 Mechanical L Page 831 Wednesday, December 31, 1969 17:00
Table 257. ELONGATION OF FERRITIC (SHEET 1 OF 2)
STAINLESS STEELS
Type
ASTM Specification
Form
Condition
Elongation (%)
Type 405 (UNS S40500)
A580 A580
Wire
Annealed Annealed, Cold Finished
20 16
Type 409 (UNS S40900) Type 429 (UNS S42900)
— —
Bar Bar
Annealed Annealed
25(a) 30(a)
Type 430 (UNS S43000)
A276 A276
Bar
Annealed, Hot Finished Annealed, Cold Finished
20 16
Type 430Ti(UNS S43036)
—
Bar
Annealed
30(a)
Type 434 (UNS S43400) Type 436 (UNS S43600)
— —
Wire Sheet, Strip
Annealed Annealed
33(a) 23(a)
(a) Typical Values Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p368 (1993).
©2001 CRC Press LLC
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Table 257. ELONGATION OF FERRITIC (SHEET 2 OF 2)
STAINLESS STEELS
Type
ASTM Specification
Form
Condition
Elongation (%)
Type 442 (UNS S44200) Type 444 (UNS S44400)
— A176
Bar Plate, Sheet, Strip
Annealed Annealed
20(a) 20
Type 446 (UNS S44600)
A276 A276
Bar
Annealed, Hot Finished Annealed, Cold Finished
20 16
(a) Typical Values Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p368 (1993).
©2001 CRC Press LLC
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Table 258. ELONGATION OF MARTENSITIC (SHEET 1 OF 3)
STAINLESS STEELS
Type
ASTM Specification
Form
Condition
Elongation (%)
Type 403 (UNS S40300)
A276 A276 A276 A276 A276 A276
Bar
Annealed, hot finished Annealed, cold finished Intermediate temper, hot finished Intermediate temper, cold finished Hard temper, hot finished Hard temper, cold finished
20 16 15 12 12 12
Type 410 (UNS S41000)
A276 A276 A276 A276 A276 A276
Bar
Annealed, hot finished Annealed, cold finished Intermediate temper, hot finished Intermediate temper, cold finished Hard temper, hot finished Hard temper, cold finished
20 16 15 12 12 12
Type 410S (UNS S41008)
A176
Plate, Sheet, Strip
Annealed
22
Type 410Cb (UNS S41040)
A276 A276 A276 A276
Bar
Annealed, hot finished Annealed, cold finished Intermediate temper, hot finished Intermediate temper, cold finished
13 12 13 12
Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p369-370 (1993).
©2001 CRC Press LLC
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Table 258. ELONGATION OF MARTENSITIC (SHEET 2 OF 3)
STAINLESS STEELS
Type
ASTM Specification
Form
Condition
Elongation (%)
Type 414 (UNS S41400)
A276 A276
Bar
Intermediate temper, hot finished Intermediate temper, cold finished
15 15
Type 414L Type 420 (UNS S42000)
— —
Bar Bar
Annealed Tempered 205 °C
20 8
Type 422 (UNS S42200)
A565
Bar
for high-temperature service
13
Type 431 (UNS S43100)
— —
Bar
Tempered 260 °C Tempered 595 °C
16 19
Type 440A (UNS S44002)
— —
Bar
Annealed Tempered 315 °C
20 5
Type 440B (UNS S44003)
— —
Bar
Annealed Tempered 315 °C
18 3
Type 440C (UNS S44004)
— —
Bar
Annealed Tempered 315 °C
14 2
Intermediate and hard tempers
Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p369-370 (1993).
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Table 258. ELONGATION OF MARTENSITIC (SHEET 3 OF 3)
STAINLESS STEELS
Type
ASTM Specification
Form
Condition
Elongation (%)
Type 501 (UNS S50100)
— —
Bar, Plate
Annealed Tempered 540 °C
28 15
Type 502 (UNS S50200)
—
Bar, Plate
Annealed
30
Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p369-370 (1993).
©2001 CRC Press LLC
8.27 Mechanical L Page 836 Wednesday, December 31, 1969 17:00
Table 259. ELONGATION OF
PRECIPITATION -HARDENING AUSTENITIC STAINLESS STEELS Type
Form
Condition
Elongation (%)
PH 13–8 Mo (UNS S13800)
Bar, Plate, Sheet, Strip
H950 H1000
6-10 6-10
15–5 PH (UNS S15500) and 17–4 PH (UNS S17400)
Bar, Plate, Sheet, Stript
H900 H925 H1025 H1075
10(a) 10(a) 12(a) 13(a)
H1100 H1150 H1150M
14(a) 16(a) 18(a)
RH950 TH1050
6 6
17–7 PH (UNS S17700)
Bar
(a) For flat rolled products, value varies with thickness. Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p371 (1993).
©2001 CRC Press LLC
8.27 Mechanical L Page 837 Wednesday, December 31, 1969 17:00
Table 260. ELONGATION OF
HIGH–NITROGEN AUSTENITIC STAINLESS STEELS
Type
ASTM Specification
Form
Condition
Elongation (%)
Type 201 (UNS S20100)
A276
Bar
Annealed
40
Type 202 (UNS S20200)
A276
Bar
Annealed
40
Type 205 (UNS S20500)
—
Plate
Annealed*
58
Type 304N (UNS S30451)
A276
Bar
Annealed
30
Type 304HN (UNS S30452)
—
Bar
Annealed
30
Type 316N (UNS S31651)
A276
Bar
Annealed
30
Data from ASM Metals Reference Book, Third Edition, Michael Bauccio, Ed., ASM International, Materials Park, OH, p367 (1993). *
Typical values
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Mechanical Properties
Table 261. TOTAL
ELONGATION OF CAST ALUMINUM ALLOYS (SHEET 1 OF 3) Alloy AA No.
Temper
Elongation (in 2 in.) (%)
201.0
T4 T6 T7
20 7 4.5
206.0, A206.0 208.0
T7 F
11.7 2.5
242.0
T21 T571 T77
1.0 0.5 2.0
T571 T61
1.0 0.5
295.0
T4 T6 T62
8.5 5.0 2.0
296.0
T4 T6 T7 F
9.0 5.0 4.5 2.0
319.0
F T6 F T6
2.0 2.0 2.5 3.0
336.0
T551 T65 T61
0.5 0.5 6.0
T51 T6 T61 T7
1.5 3.0 1.0 0.5
308.0
354.0 355.0
Source: data from ASM Metals Reference Book, Second Edition, American Society for Metals, Metals Park, Ohio 44073, (1984).
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CRC Handbook of Materials Science & Engineering
8.28 Mechanical Page 839 Wednesday, December 31, 1969 17:00
Mechanical Properties
Table 261. TOTAL
ELONGATION OF CAST ALUMINUM ALLOYS (SHEET 2 OF 3) Alloy AA No.
Temper
Elongation (in 2 in.) (%)
355.0 (Con’t)
T71 T51 T6
1.5 2.0 4.0
T62 T7 T71
1.5 2.0 3.0
T51 T6 T7
2.0 3.5 2.0
T71 T6 T7
3.5 5.0 6.0
357.0, A357.0 359.0
T62 T61 T62
8.0 6.0 5.5
360.0 A360.0 380.0
F F F
3.0 5.0 3.0
383.0 384.0, A384.0 390.0
F F F T5
3.5 2.5 1.0 1.0
A390.0
F,T5 T6 T7
1015
General purpose, type II
>1015
Moldings: Grades 5, 6, 8
>1014
High impact grade
2.0 x 1016 4 x 1014
Thermoset Carbonate
Allyl diglycol carbonate
Alkyds; Molded
Putty (encapsulating)
1014
Rope (general purpose)
1014
Granular (high speed molding) Glass reinforced (heavy duty parts) Cellulose Acetate; Molded, Extruded
1014 — 1015 1014
ASTM Grade: H6—1
1010—1013
H4—1
1010—1013
H2—1
1010—1013
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
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Electrical Properties
Table 293. VOLUME
RESISTIVITY OF POLYMERS (SHEET 2 OF 8)
Polymer Cellulose Acetate; Molded, Extruded (Con’t)
Cellulose Acetate Butyrate; Molded, Extruded
Cellusose Acetate Propionate; Molded, Extruded
Chlorinated Polymers
Polycarbonates
Diallyl Phthalates; Molded
Volume Resistivity, (ASTM D257) (Ω • cm)
Type
MH—1, MH—2
1010—1013
MS—1, MS—2
1010—1013
S2—1
1010—1013
ASTM Grade: H4
1011—1014
MH
1011—1014
S2
1011—1014
ASTM Grade: 1
1011—1014
3
1011—1014
6
1011—1014 1.5 x 1016
Chlorinated polyether Chlorinated polyvinyl chloride
1 x 1015—2 x 1016
Polycarbonate Polycarbonate (40% glass fiber reinforced)
2.1 x 1016 1.4 x 1015
Orlon filled
6 x 104—6 x 106
Dacron filled
102—2.5 x 104
Asbestos filled
102—5 x 103
Glass fiber filled
104—5 x 104
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
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Electrical Properties
Table 293. VOLUME
RESISTIVITY OF POLYMERS (SHEET 3 OF 8)
Polymer Fluorocarbons; Molded,Extruded
Type Polytetrifluoro chloroethylene (PTFCE) Polytetrafluoroethylene (PTFE) Ceramic reinforced (PTFE) Fluorinated ethylene propylene(FEP) Polyvinylidene— fluoride (PVDF)
Epoxies; Cast, Molded, Reinforced
Standard epoxies (diglycidyl ethers of bisphenol A) Cast rigid Cast flexible Molded High strength laminate
Epoxies—Molded, Extruded
High performance resins (cycloaliphatic diepoxides) Cast, rigid Molded
Volume Resistivity, (ASTM D257) (Ω • cm)
1018 >1018 1015 >2 x 1018 5 x 1014
6.1 x 1015 9.1 x 105—6.7 x 109 1—5 x 1015 6.6 x 107—109
2.10 x 1014 1.4—5.5 x 1014 >1016
Epoxy novolacs
Cast, rigid
Melamines; Molded
Filler & type Cellulose electrical
1012—1013
Glass fiber
1—7 x 1011
Alpha cellulose and mineral
1012
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
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9.1 E&M Page 978 Wednesday, December 31, 1969 17:00
Electrical Properties
Table 293. VOLUME
RESISTIVITY OF POLYMERS (SHEET 4 OF 8)
Polymer Nylons; Molded, Extruded
Volume Resistivity, (ASTM D257) (Ω • cm)
Type
Type 6 4.5 x 1013
General purpose Glass fiber (30%) reinforced Cast
2.6 x 1014
Type 8
1.5 x 1011
Type 11
2 x 1013
Type 12
1014 —1015
6/6 Nylon General purpose molding
1014—1015 2.6—5.5 x 1015
Glass fiber reinforced
Phenolics; Molded
2.8 x 1014—1.5 x 1015
General purpose extrusion
1015
6/10 Nylon General purpose
1015
Type and filler General: woodflour and flock Shock: paper, flock, or pulp
109—1013 1—50 x 1011 >1010
High shock: chopped fabric or cord
10 — 1011
Very high shock: glass fiber
10
Arc resistant—mineral Rubber phenolic—woodflour or flock Rubber phenolic—chopped fabric
1010 — 1012
Rubber phenolic—asbestos
108—1011 1011 1011
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
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CRC Handbook of Materials Science & Engineering
9.1 E&M Page 979 Wednesday, December 31, 1969 17:00
Electrical Properties
Table 293. VOLUME
RESISTIVITY OF POLYMERS (SHEET 5 OF 8)
Polymer Phenolics; Molded (Con’t)
Polymides
Polyacetals
Polyester; Thermoplastic
Type
ABS—Polycarbonate Alloy
2.2 x 1016
PVC—Acrylic Alloy PVC—acrylic Sheet
l—5 x 1013
PVC—acrylic injection molded
5 x l015
Unreinforced
4 x 1015
Glass reinforced
9.2 x 1015
Homopolymer: Standard
1 x 1015
20% glass reinforced
5 x 1014
Copolymer: Standard
1 x 1014
25% glass reinforced
1.2 x 1014
High flow
1.0 x 1014
Injection Moldings: General purpose grade
1—4 x 1016
Glass reinforced grades
3.2—3.3 x 1016
Glass reinforced self extinguishing
Polyesters: Thermosets
Volume Resistivity, (ASTM D257) (Ω • cm)
3.4 x 1016
General purpose grade
2 x 1015
Asbestos—filled grade
3 x 1014
Cast polyyester Rigid
1013
Flexible
1012
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
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979
9.1 E&M Page 980 Wednesday, December 31, 1969 17:00
Electrical Properties
Table 293. VOLUME
RESISTIVITY OF POLYMERS (SHEET 6 OF 8)
Polymer Polyesters: Thermosets (Con’t)
Volume Resistivity, (ASTM D257) (Ω • cm)
Type
Reinforced polyester moldings High strength (glass fibers) Heat and chemical resistant (asbestos) Sheet molding compounds, general purpose
Phenylene oxides (Noryl)
6.4 x 1015 —2.2 x 1016
1017
SE—1
1017
Glass fiber reinforced
1017
Standard
5 x 1016 1017
Polyarylsulfone
3.2—7.71 x l016
General purpose
>1017
High impact
Polyphenylene sulfide
1 x 1012 —1 x 1013
Phenylene Oxides SE—100
Glass fiber reinforced
Polypropylene
1 x 1012 —1 x 1013
1017
Asbestos filled
1.5 x 1015
Glass reinforced
1.7 x 1016
Flame retardant
4 x 1016—1017
40% glass reinforced
4.5 x 1014
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
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CRC Handbook of Materials Science & Engineering
9.1 E&M Page 981 Wednesday, December 31, 1969 17:00
Electrical Properties
Table 293. VOLUME
RESISTIVITY OF POLYMERS (SHEET 7 OF 8)
Polymer Polyethylenes; Molded, Extruded
Olefin Copolymers; Molded
Type Type I—lower density (0.910—0.925) Melt index 0.3—3.6
1017—1019
Melt index 6—26
1017—1019
Melt index 200
1017—1019
Type II—medium density (0.926—0.940) Melt index 20
>1015
Melt index l.0—1.9
>1015
Type III—higher density (0.941—0.965) Melt index 0.2—0.9
>1015
Melt Melt index 0.l—12.0
>1015
Melt index 1.5—15
>1015
High molecular weight
>1015
EEA (ethylene ethyl acrylate)
2.4 x 1015
EVA (ethylene vinyl acetate)
0.15 x 1015
Ionomer
Polystyrenes; Molded
Volume Resistivity, (ASTM D257) (Ω • cm)
10 x 1015
Polyallomer
>1016
Polystyrenes General purpose
>1016
Medium impact
>1016
High impact
>1016
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
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9.1 E&M Page 982 Wednesday, December 31, 1969 17:00
Electrical Properties
Table 293. VOLUME
RESISTIVITY OF POLYMERS (SHEET 8 OF 8)
Polymer Polystyrenes; Molded (Con’t)
Volume Resistivity, (ASTM D257) (Ω • cm)
Type
Glass fiber -30% reinforced
3.6 x 1016
Styrene acrylonitrile (SAN)
>1016
Glass fiber (30%) reinforced SAN Polyvinyl Chloride And Copolymers; Molded, Extruded
Nonrigid—general
1—700 x 1012
Nonrigid—electrical
4—300 x 1011
Rigid—normal impact
1014—1016
Vinylidene chloride
1014—1016
Silicones; Molded, Laminated Fibrous (glass) reinforced silicones Granular (silica) reinforced silicones Woven glass fabric/ silicone laminate Ureas; Molded
4.4 x 1016
Alpha—cellulose filled (ASTM Type l) Cellulose filled (ASTM Type 2)
(dry) 9 x 1014 5 x 1014 2—5 x 1014 0.5—5 x 1011 5—8 x 1010
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
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9.1 E&M Page 983 Wednesday, December 31, 1969 17:00
Electrical Properties
Table 294. CRITICAL
TEMPERATURE OF SUPERCONDUCTIVE ELEMENTS (SHEET 1 OF 2)
a
Element
Tc(K)
Al Be Cd
1.175 0.026 0.518-0.52
Ga Ga (β) Ga (γ) Ga (δ)
5.90-6.2 7.62 7.85
Hg (α) Hg (β)
4.154 3.949
In Ir
3.405 0.11-0.14
La (α) La (β) Mo Nb
4.88 6.00 0.916 9.25
Os Pa Pb Re
0.655 1.4 7.23 1.697
Ru Sb Sn Ta
2.6-2.7a 3.721 4.47
Tc Th
7.73-7.78 1.39
1.0833
0.493
Metastable.
Source: data from Roberts, B. W., Properties of Selected Superconductive Materials - 1974 Supplement, NBS Technical Note 825, National Bureau of Standards, U.S. Government Printing Office, Washington,D.C., 1974, 10.
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Electrical Properties
Table 294. CRITICAL
TEMPERATURE OF SUPERCONDUCTIVE ELEMENTS (SHEET 2 OF 2) Element
Tc(K)
Ti Ti
0.39 2.332-2.39
V W Zn Zr Zr (ω)
5.43-5.31 0.0154 0.875 0.53
0.65
a Metastable.
Source: data from Roberts, B. W., Properties of Selected Superconductive Materials - 1974 Supplement, NBS Technical Note 825, National Bureau of Standards, U.S. Government Printing Office, Washington,D.C., 1974, 10.
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9.1 E&M Page 985 Wednesday, December 31, 1969 17:00
Electrical Properties
Table 295. DISSIPATION FACTOR FOR (SHEET 1 OF 8)
POLYMERS
Dissipation Factor (ASTM D150) Class ABS Resins; Molded, Extruded
Acrylics; Cast, Molded, Extruded
60 Hz
106 Hz
Medium impact
0.003—0.006
0.008—0.009
High impact Very high impact Low temperature impact Heat resistant
0.005—0.007 0.005—0.010 0.005—0.01 0.030—0.040
0.007—0.015 0.008—0.016 0.008—0.016 0.005—0.015
Polymer
Cast Resin Sheets, Rods: General purpose, type I General purpose, type II Moldings: Grades 5, 6, 8 High impact grade
0.05—0.06 0.05—0.06
0.02—0.03 0.02—0.03
0.04—0.06 0.03—0.04
0.02—0.03 0.01—0.02
Thermoset Carbonate
Allyl diglycol carbonate
0.03—0.04
0.1—0.2
Alkyds; Molded
Putty (encapsulating) Rope (general purpose) Granular (high speed molding) Glass reinforced (heavy duty parts)
0.030—0.045 0.019
0.016—0.020 0.023
0.030—0.040
0.017—0.020
0.02—0.03
0.015—0.022
0.01—0.06 0.01—0.06 0.01—0.06 0.01—0.06 0.01—0.06
0.01—0.10 0.01—0.10 0.01—0.10 0.01—0.10 0.01—0.10
Cellulose Acetate; Molded, Extruded
ASTM Grade: H4—1 H2—1 MH—1, MH—2 MS—1, MS—2 S2—1
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
Shackelford & Alexander
985
9.1 E&M Page 986 Wednesday, December 31, 1969 17:00
Electrical Properties
Table 295. DISSIPATION FACTOR FOR (SHEET 2 OF 8)
POLYMERS
Dissipation Factor (ASTM D150) Class Cellulose Acetate Butyrate; Molded, Extruded
Polymer
Chlorinated Polymers Chlorinated polyether Chlorinated polyvinyl chloride
Diallyl Phthalates; Molded
0.01—0.04 0.01—0.04 0.01—0.04
0.02—0.05 0.02—0.05 0.02—0.05
0.01—0.04 0.01—0.04 0.01—0.04
0.02—0.05 0.02—0.05 0.02—0.05
0.011 0.0189— 0.0208
0.011
0.0009
0.01
0.006
0.007
0.023—0.015 (Dry) 0.004—0.016 (Dry) 0.05—0.03 (Dry) 0.004—0.015 (Dry)
0.045—0.040 (Wet) 0.009—0.017 (Wet) 0.154—0.050 (Wet) 0.012—0.020 (Wet)
ASTM Grade: 1 3 6
Polycarbonates
106 Hz
ASTM Grade: H4 MH S2
Cellulose Acetate Propionate; Molded, Extruded
60 Hz
Polycarbonate Polycarbonate (40% glass fiber reinforced) Orlon filled Dacron filled Asbestos filled Glass fiber filled
0.02
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
986
CRC Handbook of Materials Science & Engineering
9.1 E&M Page 987 Wednesday, December 31, 1969 17:00
Electrical Properties
Table 295. DISSIPATION FACTOR FOR (SHEET 3 OF 8)
POLYMERS
Dissipation Factor (ASTM D150) Class Fluorocarbons; Molded,Extruded
Epoxies; Cast, Molded, Reinforced
Epoxies—Molded, Extruded
Polymer
60 Hz
106 Hz
Polytrifluoro chloroethylene (PTFCE) Polytetrafluoroethylene (PTFE) Ceramic reinforced (PTFE) Fluorinated ethylene propylene(FEP) Polyvinylidene— fluoride (PVDF)
0.02
0.007—0.010
0.0002
0.0002
0.0005–0.0015
0.0005–0.0015
0.0003
0.0003
0.05
0.184
Standard epoxies (diglycidyl ethers of bisphenol A) Cast rigid Cast flexible Molded General purpose glass cloth laminate High strength laminate
0.0074 0.0048-0.0380 0.011-0.018
0.032 0.0369-0.0622 0.013—0.020
0.004-0.006
0.024—0.026
—
0.010-0.017
0.0055— 0.0074 0.0071—0.025 —
0.029—0.028
0.001—0.007
—
High performance resins (cycloaliphatic diepoxides) Cast, rigid Molded Glass cloth laminate Epoxy novolacs Cast, rigid
— 0.0158
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
Shackelford & Alexander
987
9.1 E&M Page 988 Wednesday, December 31, 1969 17:00
Electrical Properties
Table 295. DISSIPATION FACTOR FOR (SHEET 4 OF 8)
POLYMERS
Dissipation Factor (ASTM D150) Class Melamines; Molded
Nylons; Molded, Extruded
Polymer Filler & type Unfilled Cellulose electrical Glass fiber Alpha cellulose Mineral
106 Hz
0.048—0.162 0.026—0.192 0.14—0.23 — —
0.031—0.040 0.032—0.12 0.020—0.03 0.028 0.030
0.06—0.014
0.03—0.04
0.022—0.008
0.019—0.015
0.015 0.007—0.010
0.05 0.010—0.015
0.19 0.03
0.08 0.02
Type 6 General purpose Glass fiber (30%) reinforced Cast Flexible copolymers Type 8 Type 11 Type 12 6/6 Nylon General purpose molding Glass fiber reinforced 6/10 Nylon General purpose
Phenolics; Molded
60 Hz
Type and filler General: woodflour and flock Shock: paper, flock, or pulp High shock: chopped fabric or cord Very high shock: glass fiber
0.04 (103 Hz)
0.014—0.04 0.009—0.018
0.04 0.017—0.018
0.04
0.05—0.30
0.03—0.07
0.08—0.35
0.03—0.07
0.08—0.45
0.03—0.09
0.02—0.03
0.02
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
988
CRC Handbook of Materials Science & Engineering
9.1 E&M Page 989 Wednesday, December 31, 1969 17:00
Electrical Properties
Table 295. DISSIPATION FACTOR FOR (SHEET 5 OF 8)
POLYMERS
Dissipation Factor (ASTM D150) 60 Hz
106 Hz
0.13—0.16
0.1
0.15—0.60
0.1—0.2
0.5
0.09
0.15
0.13
ABS–Polycarbonate Alloy
0.0026
0.0059
PVC–acrylic sheet PVC–acrylic injection molded
0.076
0.094
0.037
0.031
Polyimides
Unreinforced Glass reinforced
0.003 0.0034
0.011 0.0055
Polyacetals
Homopolymer: Standard 20% glass reinforced Copolymer: Standard 25% glass reinforced High flow
0.0048 0.0047
0.0048 0.0036
0.001 (100 Hz) 0.003 (100 Hz) 0.001 (100 Hz)
0.006 0.006 0.006
Class Phenolics: Molded
PVC–Acrylic Alloy
Polyester; Thermoplastic
Polymer Arc resistant—mineral Rubber phenolic— woodflour or flock Rubber phenolic— chopped fabric Rubber phenolic— asbestos
Injection Moldings: General purpose grade Glass reinforced grades
0.002 (103 Hz) 0.002—0.003 (103 Hz)
Glass reinforced self extinguishing General purpose grade
0.002 (103 Hz)
Asbestos—filled grade
0.015 (103 Hz)
0.023 (103 Hz)
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
Shackelford & Alexander
989
9.1 E&M Page 990 Wednesday, December 31, 1969 17:00
Electrical Properties
Table 295. DISSIPATION FACTOR FOR (SHEET 6 OF 8)
POLYMERS
Dissipation Factor (ASTM D150) 60 Hz
106 Hz
0.003—0.04 0.01—0.18
0.006—0.04 0.02—0.06
0.0087—0.04
0.0086—0.022
0.0007 0.0007 0.0009
0.0024 0.0024 0.0015
0.0008 0.0019
0.0034 0.0049
Polyarylsulfone
0.0017—0.003
0.0056—0.012
General purpose
0.0005–0.0007
0.0002–0.0003 0.0002— 0.0003 0.002 0.003 0.0006–0.003
Class Polyesters: Thermosets
Polymer Cast polyyester Rigid Flexible
Reinforced polyester moldings
Sheet molding compounds, general purpose
Phenylene Oxides
SE—100 SE—1 Glass fiber reinforced Phenylene oxides (Noryl) Standard Glass fiber reinforced
Polypropylene
High impact Asbestos filled Glass reinforced Flame retardant Polyphenylene sulfide
Polyethylenes; Molded, Extruded
92 90
Thermoset Carbonate
Allyl diglycol carbonate
89—92
Alkyds; Molded
Putty (encapsulating) Rope (general purpose) Granular (high speed molding) Glass reinforced (heavy duty parts)
Opaque Opaque Opaque Opaque
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1047 Wednesday, December 31, 1969 17:00
Table 305. TRANSPARENCY OF (SHEET 2 OF 7)
POLYMERS
Polymer
Type
Transparency (visible light) (ASTM D791) (%)
Cellulose Acetate; Molded, Extruded
ASTM Grade: H6—1 H4—1 H2—1
75—90 75—90 80—90
MH—1, MH—2 MS—1, MS—2 S2—1
80—90 80—90 80—95
ASTM Grade: H4 MH S2
75—92 80—92 85—95
ASTM Grade: 1 3 6
80—92 80—92 80—92
Cellulose Acetate Butyrate; Molded, Extruded
Cellusose Acetate Propionate; Molded, Extruded
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1048 Wednesday, December 31, 1969 17:00
Table 305. TRANSPARENCY OF (SHEET 3 OF 7)
POLYMERS
Polymer
Type
Transparency (visible light) (ASTM D791) (%)
Chlorinated Polymers
Chlorinated polyether Chlorinated polyvinyl chloride
Opaque Opaque
Polycarbonates
Polycarbonate Polycarbonate (40% glass fiber reinforced)
75—85 Translucent
Fluorocarbons; Molded,Extruded
Polytrifluoro chloroethylene (PTFCE)
80—92
Epoxies; Cast, Molded, Reinforced
Standard epoxies (diglycidyl ethers of bisphenol A) Cast rigid Cast flexible Molded
90 85
General purpose glass cloth laminate High strength laminate Filament wound composite
Opaque Opaque Opaque
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1049 Wednesday, December 31, 1969 17:00
Table 305. TRANSPARENCY OF (SHEET 4 OF 7)
POLYMERS
Polymer
Type
Transparency (visible light) (ASTM D791) (%)
Epoxies—Molded, Extruded
High performance resins (cycloaliphatic diepoxides) Cast, rigid Molded Glass cloth laminate
Opaque Opaque
Epoxy novolacs
Glass cloth laminate
Opaque
Melamines; Molded
Filler & type Unfilled Cellulose electrical
Good Opaque
6/6 Nylon General purpose molding Glass fiber reinforced Glass fiber Molybdenum disulfide filled General purpose extrusion
Translucent Opaque Opaque Opaque
Nylons; Molded, Extruded
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1050 Wednesday, December 31, 1969 17:00
Table 305. TRANSPARENCY OF (SHEET 5 OF 7)
POLYMERS
Polymer
Type
Transparency (visible light) (ASTM D791) (%)
Nylons; Molded, Extruded (Con’t)
6/10 Nylon General purpose Glass fiber (30%) reinforced
Opaque Opaque
ABS–Polycarbonate Alloy
ABS–Polycarbonate Alloy
Opaque
PVC–Acrylic Alloy
PVC–acrylic sheet PVC–acrylic injection molded
Opaque Opaque
Poliymides
Unreinforced Unreinforced 2nd value Glass reinforced
Opaque Opaque Opaque
Polyesters: Thermosets
Reinforced polyester moldings High strength (glass fibers) Heat and chemical resistsnt (asbestos) Sheet molding compounds, general purpose
Opaque Opaque Opaque
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1051 Wednesday, December 31, 1969 17:00
Table 305. TRANSPARENCY OF (SHEET 6 OF 7)
POLYMERS
Polymer
Type
Transparency (visible light) (ASTM D791) (%)
Phenylene Oxides
SE—100 SE—1 Glass fiber reinforced
Opaque Opaque Opaque
Phenylene oxides (Noryl)
Glass fiber reinforced
Opaque
Polypropylene
General purpose High impact
Translucent—opaque Translucent—opaque
Asbestos filled Glass reinforced Flame retardant
Opaque Opaque Opaque
Standard 40% glass reinforced
Opaque Opaque
Polyphenylene sulfide
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1052 Wednesday, December 31, 1969 17:00
Table 305. TRANSPARENCY OF (SHEET 7 OF 7)
POLYMERS
Polymer
Type
Transparency (visible light) (ASTM D791) (%)
Polystyrenes; Molded
General purpose Medium impact High impact Glass fiber -30% reinforced
Transparent Opaque Opaque Opaque
Styrene acrylonitrile (SAN) Glass fiber (30%) reinforced SAN
Transparent Opaque
Silicones; Molded, Laminated
Fibrous (glass) reinforced silicones Granular (silica) reinforced silicones Woven glass fabric/ silicone laminate
Opaque Opaque Opaque
Ureas; Molded
Alpha—cellulose filled (ASTM Type 1) Cellulose filled (ASTM Type 2) Woodflour filled
21.8 Opaque Opaque
Styrene acrylonitrile (SAN)
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1053 Wednesday, December 31, 1969 17:00
Table 306. REFRACTIVE INDEX OF (SHEET 1 OF 5)
POLYMERS
Polymer
Type
Refractive index, (ASTM D542) (nD)
Acrylics; Cast, Molded, Extruded
Cast Resin Sheets, Rods: General purpose, type I General purpose, type II
1.485—1.500 1.485—1.495
Moldings: Grades 5, 6, 8 High impact grade
1.489—1.493 1.49
Thermoset Carbonate
Allyl diglycol carbonate
1.5
Cellulose Acetate; Molded, Extruded
ASTM Grade: H6—1 H4—1 H2—1
1.46—1.50 1.46—1.50 1.46—1.50
MH—1, MH—2 MS—1, MS—2 S2—1
1.46—1.50 1.46—1.50 1.46—1.50
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1054 Wednesday, December 31, 1969 17:00
Table 306. REFRACTIVE INDEX OF (SHEET 2 OF 5)
POLYMERS
Polymer
Type
Refractive index, (ASTM D542) (nD)
Cellulose Acetate Butyrate; Molded, Extruded
ASTM Grade: H4 MH S2
(D543) 1.46—1.49 1.46—1.49 1.46—1.49
Cellusose Acetate Propionate; Molded, Extruded
ASTM Grade: 1 3 6
1.46—1.49 1.46—1.49 1.46—1.49
Polycarbonate
1.586
Polytrifluoro chloroethylene (PTFCE) Polytetrafluoroethylene (PTFE) Fluorinated ethylene propylene(FEP) Polyvinylidene— fluoride (PVDF)
1.43 1.35 1.34 1.42
Fluorocarbons; Molded,Extruded
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1055 Wednesday, December 31, 1969 17:00
Table 306. REFRACTIVE INDEX OF (SHEET 3 OF 5)
POLYMERS
Polymer
Type
Refractive index, (ASTM D542) (nD)
Epoxies; Cast, Molded, Reinforced
Standard epoxies (diglycidyl ethers of bisphenol A) Cast rigid Cast flexible Molded
1.61 1.61
Homopolymer: Standard 20% glass reinforced 22% TFE reinforced
Opaque Opaque Opaque
Copolymer: Standard 25% glass reinforced High flow
Opaque Opaque Opaque
Cast polyyester Rigid Flexible
1.53—1.58 1.50—1.57
Polyacetals
Polyesters: Thermosets
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1056 Wednesday, December 31, 1969 17:00
Table 306. REFRACTIVE INDEX OF (SHEET 4 OF 5)
POLYMERS
Polymer
Type
Refractive index, (ASTM D542) (nD)
Phenylene oxides (Noryl)
Standard
1.63
Polyarylsulfone
Polyarylsulfone
1.651
Polyethylenes; Molded, Extruded
Type I—lower density (0.910—0.925) Melt index 0.3—3.6 Melt index 6—26 Melt index 200
1.51 1.51 1.51
Type II—medium density (0.926—0.940) Melt index 20 Melt index l.0—1.9
1.51 1.51
Type III—higher density (0.941—0.965) Melt index 0.2—0.9 Melt index 0.l—12.0 Melt index 1.5—15
1.54 1.54 1.54
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1057 Wednesday, December 31, 1969 17:00
Table 306. REFRACTIVE INDEX OF (SHEET 5 OF 5)
POLYMERS
Polymer
Type
Refractive index, (ASTM D542) (nD)
Polystyrenes; Molded
Polystyrenes General purpose Medium impact High impact
1.6 Opaque Opaque
Glass fiber -30% reinforced Styrene acrylonitrile (SAN) Glass fiber (30%) reinforced SAN
Opaque 1.565—1.569 Opaque
Vinylidene chloride
1.60—1.63
Polyvinyl Chloride And Copolymers; Molded, Extruded
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1058 Wednesday, December 31, 1969 17:00
Table 307. DISPERSION OF OPTICAL (SHEET 1 OF 13) Material
Dispersion Equation at 298 K
3
Alumina (Sapphire, Single Crystal)
MATERIALS
2
n -1=
Σ i=1
Aiλ 2 λ2
-
(λ in µm)
λ2 i
where i
1 2 3 (λ in mm)
λi2 0.00377588 0.0122544 321.3616
Ai 1.023798 1.058264 5.280792
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1059 Wednesday, December 31, 1969 17:00
Table 307. DISPERSION OF OPTICAL (SHEET 2 OF 13) Material
Dispersion Equation at 298 K
5
ArsenicTrisulfide (Glass)
MATERIALS
2
n -1=
Σ i=1
Kiλ 2 λ 2 − λi2
where i
1 2 3 4 5 (λ in µm)
(λ in µm)
λi2 0.0225 0.0625 0.1225 0.2025 0.705
Ki 1.8983678 1.9222979 0.8765134 0.1188704 0.9569903
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1060 Wednesday, December 31, 1969 17:00
Table 307. DISPERSION OF OPTICAL (SHEET 3 OF 13) Material
Dispersion Equation at 298 K
3
Barium Fluoride (Single Crystal)
MATERIALS
2
n -1=
Σ
Aiλ 2
(λ in µm)
λ2 - λ2 i i=1
where i
1 2 3 (λ in µm)
λi 0.057789 0.10968 46.3864
Ai 0.643356 0.50676 3.8261
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1061 Wednesday, December 31, 1969 17:00
Table 307. DISPERSION OF OPTICAL (SHEET 4 OF 13) Material
Cadmium Sulfide (Bulk and Hexagonal Single Crystal)
MATERIALS
Dispersion Equation at 298 K
n 2o=5.235+
1.891x107 λ 2-1.651x107
for ordinary ray, and
2.076x10 7 2 ne =5.239+ λ 2-1.651x10 7 for extraordinary ray. (λ in µm)
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1062 Wednesday, December 31, 1969 17:00
Table 307. DISPERSION OF OPTICAL (SHEET 5 OF 13) Material
Dispersion Equation at 298 K
3
Calcium Fluoride (Single Crystal)
MATERIALS
2
n -1=
Aiλ 2
Σ i=1
λ2
-
(λ in µm)
λ2 i Ai 0.5675888 0.4710914 3.8484723
i 1 2 3
Cesium Bromide (Single Crystal)
2 -6 n = 5.640752–3.338x10 λ2 +
0.0018612 λ
2
λι 0.050263605 0.1003909 34.64904
41110.49 0.0290764 + 2 + 2 λ -14390.4 λ -0.024964
(λ in µm)
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1063 Wednesday, December 31, 1969 17:00
Table 307. DISPERSION OF OPTICAL (SHEET 6 OF 13) Material
Dispersion Equation at 298 K
5
Cesium Iodide (Single Crystal)
MATERIALS
2
n -1=
Σ i=1
Kiλ 2 λ 2 − λi2
where i
1 2 3 4 5 (λ in mm)
(λ in µm)
λi2 0.00052701 0.02149156 0.28551800 0.39743178 3.3605359
Ki 0.3461725 1.0080886 0.02149156 0.044944 25921
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1064 Wednesday, December 31, 1969 17:00
Table 307. DISPERSION OF OPTICAL (SHEET 7 OF 13)
MATERIALS
Material
Dispersion Equation at 298 K
Germanium (Intrinsic Single Crystal)
n = A + Bλ + Cλ2 + Dλ2 + Eλ4
where A=3.99931 B=0.391707 C=0.163492 D=–0.0000060 E=0.000000053 for 2.0µm ≤ λ ≤ 13.5 µm
Lithium Fluoride (Single Crystal)
n = A + BL + CL2 + Dλ2 + Eλ4
where A=1.38761 B=0.001796 C=–0.000041 D=–0.0023045 E=–0.00000557 for 0.5µm ≤ λ ≤ 6.0 µm Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1065 Wednesday, December 31, 1969 17:00
Table 307. DISPERSION OF OPTICAL (SHEET 8 OF 13) Material
MATERIALS
Dispersion Equation at 298 K
Magnesium Fluoride (Single Crystal)
no =1.36957 +
0.0035821 λ -0.14925
for ordinary wavelengths, and
ne =1.38100 +
0.0037415 λ -0.14947
for wavelengths within 0.4µm ≤ λ ≤ 0.7 µm
2 -5 n =2.956362-0.1062387 λ 2 –2.04968 x10 λ4
Magnesium Oxide (Single Crystal)
–
0.0219577 λ2
-0.01428322
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1066 Wednesday, December 31, 1969 17:00
Table 307. DISPERSION OF OPTICAL (SHEET 9 OF 13) Material
Potassium Bromide (Single Crystal)
Potassium Chloride (Single Crystal)
MATERIALS
Dispersion Equation at 298 K
2
n = 2.3618102–0.00058072 λ 2 +
0.02305269
λ2– 0.02425381 for 0.4µm ≤ λ ≤ 0.7 µm
n2= 2.174967+
0.08344206 λ 2-0.0119082
+
0.00698382 λ2 -0.025555
– 0.000513495 λ2 – 0.06167587 λ 4 for ultraviolet wavelengths
n2=3.866619+
0.08344206 λ 2 – 0.0119082
–
0.00698382 λ 2–
0.025555
–
5569.715 λ 2–
3292.472
for the visible light Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1067 Wednesday, December 31, 1969 17:00
Table 307. DISPERSION OF OPTICAL (SHEET 10 OF 13) Material
Silica (High Purity Fused)
Silicon (Single Crystal)
MATERIALS
Dispersion Equation at 298 K
n2=2.978645 +
0.008777808 λ 2–
0.010609
+
84.06224 λ 2–
96.0000
n = 3.41696 + 0.138497L + 0.013924L2 – 0.0000209λ2 + 0.000000148λ4
where L = (λ2 – 0.028)–1
Silver Bromide (Single Crystal)
n2 – 1 0.10279 λ2 =0.48484+ λ2– 0.0900 n2 + 2
– 0.004796 λ 2
for 0.54µm ≤ λ ≤ 0.65 µm
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1068 Wednesday, December 31, 1969 17:00
Table 307. DISPERSION OF OPTICAL (SHEET 11 OF 13)
MATERIALS
Material
Dispersion Equation at 298 K
Silver Chloride (Single Crystal)
n = 4.00804 – 0.00085111λ2 – 0.00000019762λ4 + 0.079086/(λ2 – 0.04584)
Strontium Titanate (Single Crystal)
n = A + BL + CL2 + Dλ2 + Eλ4
where A=2.28355 B=0.035906 C=0.001666 D=–0.0061355 E=–0.00001502 for 1.0 µm ≤ λ ≤ 5.3 µm
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1069 Wednesday, December 31, 1969 17:00
Table 307. DISPERSION OF OPTICAL (SHEET 12 OF 13) Material
Dispersion Equation at 298 K
5
Thallium Bromoiodide (KRS-5, Mixed Crystal)
MATERIALS
2
n -1=
Σ i=1
Kiλ 2 λ 2 − λi2
where i
1 2 3 4 5 (λ in µm)
λi2 0.0225 0.0625 0.1225 0.2025 27089.737
Ki 1.8293958 1.6675593 1.1210424 0.4513366 12.380234
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
10.2 Optical L Page 1070 Wednesday, December 31, 1969 17:00
Table 307. DISPERSION OF OPTICAL (SHEET 13 OF 13) Material
Titanium Dioxide (Rutile, Single Crystal)
MATERIALS
Dispersion Equation at 298 K
n 2o=5.913+
2.441x107 λ 2– 0.803x107
for ordinary wavelengths, and
2 n =7.197 e
+
3.322x10
7
λ 2– 0.843x107
for extraordinary wavelengths. (λ in Å) Zinc Sulfide (Single Crystal, Cubic)
7 n = 5.164+ 1.208x107 l2 – 0.732 x10 (λ in Å)
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
Shackelford, James F. & Alexander, W. “Chemical Properties of Materials” Materials Science and Engineering Handbook Ed. James F. Shackelford & W. Alexander Boca Raton: CRC Press LLC, 2001
11.0 Chemical Page 1071 Wednesday, December 31, 1969 17:00
CHAPTER 9
List of Tables
Chemical Properties of Materials
Absorption Water Absorption of Polymers EMF Potentials and Galvanic Series Standard Electromotive Force Potentials Galvanic Series of Metals Galvanic Series of Metals in Sea Water Corrosion Corrosion Rate of Metals in Acidic Solutions Corrosion Rate of Metals in Neutral and Alkaline Solutions Corrosion Rate of Metals in Air Corrosion Rates of 1020 Steel at 70˚F Corrosion Rates of Grey Cast Iron at 70˚F Corrosion Rates of Ni–Resist Cast Iron at 70˚F Corrosion Rates of 12% Cr Steel at 70˚ Corrosion Rates of 17% Cr Steel at 70˚F Corrosion Rates of 14% Si Iron at 70˚F Corrosion Rates of Stainless Steel 301 at 70˚F Corrosion Rates of Stainless Steel 316 at 70˚F Corrosion Rates of Aluminum at 70˚F Corrosion Resistance of Wrought Coppers and Copper Alloys Corrosion Rates of 70-30 Brass at 70˚F
©2001 CRC Press LLC
1071
11.0 Chemical Page 1072 Wednesday, December 31, 1969 17:00
Chemical Properties List of Tables (Continued)
Corrosion (con’t) Corrosion Rates of Copper, Sn-Braze, Al-Braze at 70˚F Corrosion Rates of Silicon Bronze at 70˚F Corrosion Rates of Hastelloy at 70˚F Corrosion Rates of Inconel at 70˚F Corrosion Rates of Nickel at 70˚F Corrosion Rates of Monel at 70˚F Corrosion Rates of Lead at 70˚F Corrosion Rates of Titanium at 70˚F Corrosion Rates of ACI Heat–Resistant Castings Alloys in Air Corrosion Rates for ACI Heat–Resistant Castings Alloys in Flue Gas Flammability Flammability of Polymers Flammability of Fiberglass Reinforced Plastics
©2001 CRC Press LLC
1072
CRC Handbook of Materials Science & Engineering
11.1 Chemical L Page 1073 Wednesday, December 31, 1969 17:00
Table 308. WATER
ABSORPTION OF POLYMERS (SHEET 1 OF 12)
Polymer
Type
Water Absorption in 24 hr, ASTM D570) (%)
ABS Resins; Molded, Extruded
Medium impact High impact
0.2—0.4 0.2—0.45
Very high impact Low temperature impact Heat resistant
0.2—0.45 0.2—0.45 0.2—0.4
Cast Resin Sheets, Rods: General purpose, type I General purpose, type II
0.3—0.4 0.2—0.4
Moldings: Grades 5, 6, 8 High impact grade
0.3—0.4 0.2—0.4
Allyl diglycol carbonate
0.2
Acrylics; Cast, Molded, Extruded
Thermoset Carbonate
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
11.1 Chemical L Page 1074 Wednesday, December 31, 1969 17:00
Table 308. WATER
ABSORPTION OF POLYMERS (SHEET 2 OF 12)
Polymer
Type
Water Absorption in 24 hr, ASTM D570) (%)
Alkyds; Molded
Putty (encapsulating) Rope (general purpose) Granular (high speed molding) Glass reinforced (heavy duty parts)
0.10—0.15 0.05—0.08 0.08—0.12 0.007—0.10
Cellulose Acetate; Molded, Extruded
ASTM Grade: H4—1 H2—1
1.7—2.7 1.7—2.7
MH—1, MH—2 MS—1, MS—2 S2—1
1.8—4.0 2.1—4.0 2.3—4.0
ASTM Grade: H4 MH S2
2 1.3—1.6 0.9—1.3
Cellulose Acetate Butyrate; Molded, Extruded
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
11.1 Chemical L Page 1075 Wednesday, December 31, 1969 17:00
Table 308. WATER
ABSORPTION OF POLYMERS (SHEET 3 OF 12)
Polymer
Type
Water Absorption in 24 hr, ASTM D570) (%)
Cellusose Acetate Propionate; Molded, Extruded
ASTM Grade: 1 3 6
1.6—2.0 1.3—1.8 1.6
Chlorinated Polymers
Chlorinated polyether Chlorinated polyvinyl chloride
0.01 0.11
Polycarbonates
Polycarbonate Polycarbonate (40% glass fiber reinforced)
0.15 0.08
Orlon filled Dacron filled Asbestos filled Glass fiber filled
(122 •F, 48 hr), % 0.2—0.5 0.2—0.5 0.4—0.7 0.2—0.4
Diallyl Phthalates; Molded
Source: data compiled by J.S. Park from Charles T. Lynch, CRC Handbook of Materials Science, Vol. 3, CRC Press, Boca Raton, Florida, 1975 and Engineered Materials Handbook, Vol.2, Engineering Plastics, ASM International, Metals Park, Ohio, 1988.
©2001 CRC Press LLC
11.1 Chemical L Page 1076 Wednesday, December 31, 1969 17:00
Table 308. WATER
ABSORPTION OF POLYMERS (SHEET 4 OF 12)
Polymer
Type
Water Absorption in 24 hr, ASTM D570) (%)
Fluorocarbons; Molded,Extruded
Polytrifluoro chloroethylene (PTFCE) Polytetrafluoroethylene (PTFE)
0 0.01
Ceramic reinforced (PTFE) Fluorinated ethylene propylene(FEP) Polyvinylidene— fluoride (PVDF)
>0.2