254
PHYSICS: L. W. MCKEEHAN
PROC. N. A. S.
investigation to other metals. Targets of the various metals can be insert...
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254
PHYSICS: L. W. MCKEEHAN
PROC. N. A. S.
investigation to other metals. Targets of the various metals can be inserted and the characteristics of each studied under the same conditions by moving them successively into the path of the primary electron stream. There is no reason to believe that the secondary electron characteristics should be the same for all metals, and a knowledge of their characteristics in this respect should be of value in connection with the electron theory of metals. A more detailed account of this work will be published in the Physical Review in the near future. 'Gehrts, Ann. Physik, 36, 1911, p. 995. 0. von Baeyer, Physik. Zs., 10, 1909, p. 176; Deut. Phys. Ges., Verh., 10, 24,1908, p. 953; Ber. D. Physik Ges., 10, 1910, p. 96 and p. 953. N. R. Campbell, Phil. Mag., 22, 1911, p. 276; 24, 1912, p. 527; 25, 1913, p. 803; 28, 1914, p. 286; 29, 1915, p. 369. A. W. Hull, Physic. Rev. 7, 1916, p. 1. F. Horton and Miss A. C. Davies, Roy. Soc. Proc. London, 97A, 1920, p. 23. I. G. Barber, Physic. Rev., 17, 1921, p. 322. Davisson and Kunsman, Science, 54, 1921, p. 522.
THE CRYSTAL STRUCTURE OF POTASSIUM By L. W. MCKEEHAN RZSSARCH LABORATORIgS oF THE AMERICAN TULVPHONE AND TELEGRAPH COMPANY, AND THU WESTERN ELECTRIC COMPANY, INCORPORATUD.
Communicated June 13, 1922
Potassium, when examined by X-rays at room temperature appears to be amorphous, as previously reported by Hull.I But if potassium, cast in a thin-walled cylindrical glass tube, is cooled to -150° C. in a current of air by the method recently employed in getting the crystal structure of mercury,2 large crystals, giving well marked reflections of the K-radiation of molybdenum, are formed. These crystals are, in fact, so large that it is a matter of some difficulty to obtain enough different orientations in a single sample, and the data are not of great accuracy. Continuous rotation of the sample about the axis of the cylinder so weakens the intensity of the occasional reflections that they can no longer be located with certainty. The best results are obtained by rotating the sample through small angles at such long time-intervals that individual crystals in suitable orientations have long enough to affect the film. The best fit wvith the data is furnished by assuming the atoms to be arranged in a body-centered cubic lattice with a = 5.20 X 10-8 cm. and therefore with a density 0.92 gm./cm.3 This density is higher than
VOL. 8, 1922
PHYSICS: R. C. WILLIAMSON
255
the commonly accepted value, 0.862 gm./cm.3, partly no doubt on account of the low temperature of the crystals, and partly perhaps because the values usually quoted have been obtained for metal not perfectly crystalline, to judge by the X-ray evidence. As regards the purity of the potassium here used, it can only be stated that the original material was purchased as "c. p." from Eimer and Amend, was dried and freed from the usual oily surface layer, and was then melted and double-distilled in vacuo using only pyrex glass. The samples were prepared for me under the supervision of Dr. H. E. Ives from material used by him in the preparation of photoelectric cells. His suggestion that a change in the crystalline condition of the metal at low temperatures might be responsible for certain anomalies in photoelectric emission was the starting point of this research. The observed crystalline structure does not persist when the temperature is allowed to rise again to about 20° C. No effort has been made to determine the highest temperature at which crystallinity can still be detected, since it seems probable that the loss of structural symmetry is, not abrupt but gradual. 1 A. W. Hull, Physic. Rev., (2) 10, 661-696 (Dec., 1917). 2 L. W. McKeehan and P. P. Cioffi, Ibid., (2) 19, 444-446 (April, 1922).
PRELIMINARY REPORT ON THE IONIZATION OF POTASSIUM VAPOR BY LIGHT BY R. C. WILLIAMSON DIPARTMZNT OF PHysics, UNIVERSITY OF WISCONSIN Communicated June 13, 1922
As Hughes states in a Bulletin of the NATIONAL RISEARCH COUNciL,1 experimental results relative to the ionization of metallic vapors by light, have been very meagre, and it is difficult to point to any phenomena which are due, without doubt, to ionization by radiation of optical frequencies. Steubing2 describes ionization of mercury vapor by light transmitted through fused quartz, but his results seem probably to be explained as ionization in the vapor by collision of photoelectrons from the electrodes. Anderson3 and Gilbreath4 have published results obtained in potassium vapor which seem to be due to wall emission. Kunz and Williams,r in a brief abstract, state that while caesium was not ionized by radiation of wave-lengths greater than 3130 A, a marked effect was secured at 2530 A.. No details as to the method have as yet come to the writer's notice. The equation Ve = hp, where V is the voltage corresponding to the