2-Knots and their Groups (Australian Mathematical Society Lecture Series, No. 5)

AuslJ'alian Mathematical Society Lecture Series. 5

2-Knots and their Groups Jonathan Hillman Macquarie University, Australia

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CAMBRIDGE UNIVERSITY PRESS Cambridge

New York New Rochelle Melbourne Sydney

CAMBRIDGE UNIVERSITY PRESS Cambridge, New York, Melbourne, Madrid, Cape Town, Singapore, Silo Paulo, Delhi Cambridge University Press The Edinburgh Building, Cambridge CB2 8RU, UK Published in the United States of America by Cambridge University Press, New York www.cambridge.org Information on this title: www.cambridge.org/9780521371735 © Cambridge University Press 1989

This publication is in copyright. Subject to statutory exception and to the provisions of relevant collective licensing agreements, no reproduction of any part may take place without the written permission of Cambridge University Press. First published 1989 Re-issued in this digitally printed version 2008 A catalogue record/or this publication is available/rom the British Library ISBN 978-0-521-37173-5 hardback ISBN 978-0-521-37812-3 paperback

CONTENTS

Preface 1

Chapter 1

Knots and Related Manifolds

Chapter 2

The Knot Group

15

Chapter 3

Localization and Asphericity

36

Chapter 4

The Rank 1 Case

52

Chapter 5

The Rank 2 Case

70

Chapter 6

Ascending Series and the Large Rank Cases

85

Chapter 7

The Homotopy Type of

Chapter 8

Applying Surgery to Determine the Knot

124

Appendix A

Four-Dimensional Geometries and Smooth Knots

142

Appendix B

Reflexive Cappell-Shaneson 2-Knots

145

M(K)

107

Some Open Questions

147

References

150

Index

164

(vii)

Pour Jes noeuds de S2 en S4 on ne sait pas grand chose Preface

Since Gramain

wrote

the above

words

in

a Seminaire

Bourbaki

report on classical knot theory in 1976 there have been major advances in 4-dimensional

topology, by

Casson, Freedman

and

Quinn. Although a com-

plete classification of 2-knots is not yet in sight, it now seems plausible to expect a characteriza tion of knots in some significant classes in terms of invariants related to the knot group. Thus the subsidiary problem of characterizing 2-knot groups is an essential part of any attempt

to classify 2-

knots, and it is the principal topic of this book, which is largely algebraic in

tone. However we also draw upon 3-manifold theory (for the construc-

tion of many examples) and 4-dimensional surgery (to establish uniqueness of knots with given invariants). It is the interplay between algebra and 3and 4-dimensional topology that makes

the study of 2-knots of particular

interest. Kervaire

gave

homological

conditions

which

characterize

high

dimensional knot groups and which 2-knot groups must satisfy, and showed that any high dimensional knot group with a presentation of deficiency 1 is a 2-knot group. Bridging the gap between the homological and combinatorial conditions appears to be a delicate

task. For much of this book we shall

make a further algebraic assumption, namely that the group have an abelian normal subgroup of rank

at

least

1. This is satisfied by

the

groups

of

many fib red 2-knots, including all spun torus knots and cyclic branched covers of twist spun knots. The evidence suggests that if the abelian subgroup has rank at least 2

then

the group is among

these, and

the problem is

then related to that of characterizing 3-manifold groups and their automorphisms. Most known knots

with such groups can be characterized algebrai-

cally, modulo the s -cobordism theorem. However in are examples which are not

the rank 1 case there

the groups of fibred knots, and here less is

known. The other class of groups contains

that

is

of

particular interest

the groups of (spun) classical knots consists of

cohomological dimension

2 and deficiency

1.

(If

some

as

it

those which have

standard conjectures

hold these conditions are equivalent for knot groups). One striking member of this class is the group 4> with presentation , whose

(viii) commutator subgroup is a torsion free rank 1 abelian group. All other knot groups

with

deficiency

1

groups are iterated free

and nontrivial

torsion

free

abelian

normal

sub-

products of torus knot groups, amalgamated over

central copies of Z, and are the groups of fib red 2-knots. We show that any

knot

with such

commutator

a

subgroup)

group (and more generally, whose can

be

cobordism theorem. Together

characterized

algebraically,

these two classes contain

group has

the

free

the

s-

gronps of

the

modulo

most familiar and important examples of 2-knots. However we have by no means

completed

their

classification,

and

the

problem

of

organizing

the

groups outside these classes remains quite open. (The formation of snms and satellites should play a part here). We shall now outline the chapters in somewhat greater detail. In Chapter

1

we

give

the

basic definitions

and

background

results

on

the

geometry of knots and we show how the classification of higher dimensional knots can be reduced (essentially) to the classification of the closed manifolds built from the ambient spheres by surgery on such knots. As far as possible these definitions and results have been formulated so as to apply in

all dimensions.

We have chosen to work in

the TOP category

as our

chief interest is in the 4-dimensional case, where PL or (equivalently) DIFF techniques are not yet adequate. In Chapter 2 we give Kervaire's characterization of high dimensional knot groups, and varia tions on

this

theme: link groups, commuta tor

subgroups of knot groups, centres of knot groups. We also give his partial results

on

2-knot

groups.

Counter

examples

to

show

that

not

all

high

dimensional knot groups can be 2-knot groups were found independently by various people; most of their arguments used duality in the infinite cyclic cover of the exterior of the knot. We review some of these arguments, and we

show

the exterior of a nontrivial n -knot with n > 1 is never

that

aspherical, giving Eckmann's proof via duality in the universal cover. Chapter 3 contains our key result. We show that in contrast to the

theorem

of

Dyer-Vasquez

and

Eckmann

just

quoted

the

closed

4-

manifold obtained by surgery on a 2-knot is often aspherical. If T is the maximal locally-finite normal subgroup of a 2-knot group rr and rr/T has an abelian normal subgroup of rank 1 such that the quotient has finitely many

ends

redundan t)

and holds

if

a

further,

then

ei ther

technical condition rr'

is

fini te

or

(that

may

rr/T = 4>

or

prove

to

be

rr/T

is

an

(ix) orientable Poincare duality group over Q of formal dimension 4. The latter is also true if "IT has an abelian normal subgroup of rank greater than 1.

In the next three chapters we examine these cases separately. In Chapter 4 we determine the 2-knot groups with finite commutator subgroup. All of these can be realized by fibred 2-knots, and many by twist spun classical knots. We show also that if "IT = and T is nontrivial then it must be infinite; in fact we believe that in this case T must be trivial. In Chapters 5 and 6 we consider the Poincare duality cases. further subdivision of cases, according

to

Here there is a

the rank of the abelian normal

subgroup (which must be at most 4). All the known examples with a torsion free abelian normal subgroup of rank 2 derive from twist spun torus knots. The groups of aspherical Seifert fibred 3-manifolds may be characterized as

PD 3 -groups which have subgroups of finite index with nontrivial centre and infinite abelianization. Using

this, we give an algebraic characterization of

the groups of 2-knots which are cyclic branched covers of twist spins of torus knots.

In Chapter 6 we determine the 2-knot groups with abelian normal

subgroups

of

rank

greater

than

2,

and

the

results

of

these

three

chapters are combined to show that if " has an ascending series whose factors are locally-finite or locally-nilpotent, then it is in fact

locally-finite

by solvable. If moreover " has an abelian normal subgroup of positive rank then it is finite by solvable, and we describe all such groups. (We doubt that there are any other 2-knot groups with such ascending series).

In

the last

two chapters

we

attempt

to

recover 2-knots

group theoretic invariants. As we observe in Chapter 1 a knot K

from

is deter-

mined up to changes of orientation and "Gluck reconstruction" by a certain closed 4-manifold "l(M).

We

first

M(K)

try

together with a conjugacy class in the knot group

to determine

the

homotopy

type

of

M

in

terms of

algebraic invariants. The problem of the homeomorphism type may then be reduced to standard questions of surgery. For knots whose group is torsion free and polycyclic we are completely successful, for the surgery techniques are then available to solve the problem. We show also that if the commutator subgroup is an infinite, nonabelian nilpotent group then, excepting for two such groups, the knot is determined up to inversion by its group alone.

Freedman has shown that surgery techniques apply whenever the group is

as in

Chapter 6, but

in general it is difficult

to compute

the

obstructions. On the other hand, for many fibred 2-knots we can determine the (simple) homotopy type and show that the snrgery obstructions are 0, but

it

is

not

yet

known

whether

s -cobordisms with such

5-dimensional

groups are always products. After Chapter 8 the

4-dimensional

there

geometries

are

that

two appendices. The can

be

supported

first

by

considers

some

M(K).

(Among these are some complex surfaces). In the second it is shown that certain CappeU-Shaneson 2-knots are reflexive if and only if every totally positive unit in the cubic number field generated by a root of the Alexander polynomial is a square in tha t field. After there is a list of open questions on 2-knots and related topics. Some of these are well known and very

difficult;

others

are

more

technical

and

algebraic,

but

have

also

resisted solution so far. As the algebra used in this book may perhaps be unfamiliar for many topologists we would like to stress here tha t our principal references have been the Queen Mary College lecture notes of Bieri for homological group theory, and the text of Robinson for other aspects of group theory. I Groves,

Laci

would

like

Kovacs,

to

Peter

thank

William

Kropholler,

Dunbar,

Darryl

Ross

Geoghegan, John

McCullough,

Mike

Mihalik,

Peter M. Neumann, Steve Plotnick, Peter Scott and Shmuel Weinberger for their correspondance and advice on various aspects of this work. I would also like to acknowledge the support of the U.K. Science and Engineering Research Council (as a Visiting Fellow at the University of Durham), which enabled me

to meet

Peter Kropholler and

Peter Scott, and of

the Aus-

tralian Research Grants Scheme, for a grant which brought Steve Plotnick to Macquarie University in mid-1987.

Macquarie University

Chapter 1

KNOTS AND RELATED MANIFOLDS In this chapter are the basic definitions and constructions of the

objects that we shall study. In particular we show how the classification of higher dimensional knots can be reduced (essentially) to the classification of certain closed manifolds. We also give a number of results on the geometry of

these

them in braic).

objects,

for

the

most

part

without

proof, as

we

a crucial way in our arguments later (which are

shall not primarily

use alge-

We shall first state some of our conventions on notation and termi-

nology. Let

Dn = {

<x 1'... x n > in R n: LX

l

~ 1 } be

n -disc and

the

let Sn = aD n +l be the n-sphere. The standard orientation of R n induces an orientation of D n , and hence one of Sn-l by the convention that the boundary of an oriented manifold be oriented compatibly with inward normal last (cf. (RS:

pages 44-45]).

We

shall always

taking assume

the that

these standard discs and spheres have been given such standard orientations. An embedding is a 1-1 map which is a homeomorphism onto its image. All

isotopies of locally

flat

embeddiligs

of manifolds

in

manifolds

shall be ambient isotopies. The inclusion of R n +1 into R n +2 as the hyperplane defined by the equa tion x n +2 = 0 induces the equa toria! embedding

eo:S n -. Sn+l. The interior of a subset N of a topological space shall be denoted by int N. The expression A ~ B means that the objects A morphic

in

some

category

appropriate

to

the

context.

and B are iso-

When

there

is

a

canonical isomorphism, or after a particular isomorphism has been chosen, we shall

write

A

=

B.

(For

instance

the

fundamental

infinite cyclic, and choosing an isomorphism with Z

group

of

a

circle

is

corresponds to choosing

an orientation for the circle). Qualifications shall usually be omitted when there is no risk of ambiguity. In particular, we may abbreviate X(K), M(K) and TTK as X, M and

7T

respectively.

Knots An n -knot is a locally flat embedding K:S n _ Sn+2. also use when

n

the ~

2

terms "classical knot" and

"high dimensional

(We shall

when n = 1, "higher dimensional knot" knot"

when

n

~

3).

Such

a

knot

is

2

Knots and Related Manifolds

determined up

to isotopy

by

its image

K(Sn), considered

as

an oriented

codimension 2 submanifold of Sn+2, and so we may let K also denote this submanifold. Two n -knots KO and K1 are isotopic if (and only if) there is an

orien ta tion

preserving

hKO -= K 1, for such a map h

Thus for instance if rn Sn

homeomorphism

self

b

of

tinct. (Note

that

the

that

such

is isotopic to the identity [KS: page 292].

is an orientation reversing self homeomorphism of

the knots K, rK

unoriented

So+2

rK p may all be dis-

images of K

submanifolds).

The

and K p

knot

K

is

are

the same, considered as

invertible,

+amphicheiraJ

or

-amphicheiral if it is isotopic to K p, rK or -K respectively. An n -knot is trivial if it is isotopic to the unknot e n + 1 en .

By the uniqueness of discs

an n -knot is trivial if and only if it bonnds a locally flat (n+1)-disc in Sn+2. ~

If n

unique j

up

to

4 then each n -knot is isotopic to a PL n -knot which is

PL (ambient) isotopy,

for

then

Hi(Sn +2,K;Z/2Z) = 0

for

= 3 and 4, so the Kirby-Siebenmann obstructions to existence and unique-

ness of PL triangulations vanish [KS: Essay IV.10]. All the examples of 2knots that we shall construct below shall be PL with respect to some triangulation of S4. However as it is not yet known whether all

triangula-

tions of S4 are PL equivalent, and as the 4-dimensional surgery techniques that we wish to use to characterize certain 2-knots have only been established in the TOP category (and then only for a restricted class of fundamental groups), the above definition of knot seems most snitable. The exterior Every (locally flat) n -knot with n = 2 is flat [KS 1975) and so there is an embedding j:Sn XD 2 -

K;' such

tha t

We may assume to isotopy

tha t j

Sn+2 onto a closed neighbourhood N of

and

K

j i Sn X{O}

aN -

j(Sn XS 1) is

bicollared

in

Sn +2.

is orienta tion preserving, and then it is uniqne up

rei SnX{O}. These results (and

their proofs) remain valid when

n = 2, by Quinn's solution of the 4-dimensional annulus conjecture, together

with surgery over Z (cf. [Qu 1982] and [PQ]). The

exterior

of

K

is

the

compact

(n +2)-manifold

X(K) =

Sn+2-int N, which is well defined up to homeomorphism as N is unique up

Knots and Related Manifolds

3

to isotopy rei K. It inherits an orientation from Sn+2, and has boundary homeomorphic to SnXS1.

The interior of X

complement Sn+2-K. The knot group

is homeomorphic to the knot

(X(K». By general posi1 tion, every element of 'irK can be represented by an oriented simple closed

curve in X, and if n class of maps

from

~

S1

is 'irK =

'lr

2 each conjugacy class in 'irK (i.e. free homotopy to

X)

corresponds

to

an unique

isotopy class of

such curves. In particular, any orien ted simple closed curve isotopic to the oriented boundary of a transverse disc (i.e. to {j(s)}XS 1 ) is called a meridian

of K, and we shall also use

this term to denote

the corresponding

elemen ts of 'irK. By Alexander duality H/X;Z) ~ Z erwise. The

meridians are

all

if i = 0 or 1 and is 0 oth-

homologous and

generate

H 1 (X;Z)

(by

the

Mayer-Vietoris sequence for Sn+2 = XuSnXD2) and so determine a canonical isomorphism H 1(X;Z) = Z. The exterior of a

trivial n -knot is homeomorphic to Dn+lxS1.

Conversely if X(K) is homotopy equivalent

to

S1

then K

is

trivial [Pa

1957, St 1963, Le 1965, Sh 1968, Fr 19831. For if 'I is a meridian in the interior of X, it has a product neighbourhood U (as X if X '" S 1 n ~ 3. It is

then

X -int U

is an

s -cobordism and

then easy to see that K

so

is orientable) and a product, provided

bounds a disc in Sn +2. (This argu-

ment works also in the PL and DIFF categories). This criterion for triviality is also correct when n = 1 [Pa 1957) and n = 2 [Fr 19831, although the proofs are different. (Note that there may be PL 2-knots with group Z

which are not PL isotopic to the unknot). The assumption on X

can be

weakened considerably (see below); in particular if n = 1 or 2 an n -knot is trivial if and only if its group is infinite cyclic. Gluck

showed

that

when

n

= 2

the

group

of

pseudoisotopy

classes of self homeomorphisms of SnxS1 is (ZI2Z)3, generated by reflections in either factor and by the map all x

in Sn

and y

in S1, where 8:S 1

t"

given by

t"(x ,y) =

(8(yXx),y)

for

SO(n+l) is an essential map [GI

19621. Browder and Kato extended his result to all higher dimensions [Br 1967,

Ka Dn+1xS 1

19691.

As

(provided

any

self

n ~ 2),

homeomorphism the

closed

of

SnxSl

extends

(n+2)-manifold

across

M(K) =

X(K\.JD n +1 xS 1 obtained from Sn+2 by surgery on K is also well defined,

4

Knots and Related Manifolds

and it inherits an orientation from Sn+2 via X. Since up to homotopy X is the complement of {O}XSI in M, the inclusion of X isomorphism"K

by

"I(M),

characteristic of M is X(M) =

=

general

position

into M

induces an

n ;> 2).

(for

X(Sn +2)_X(Sn XD 2 )+X(D n +1xSl)

The

=

Euler

O. In fact

0, I, n +1 or n +2 and is 0 otherwise, as follows

easily from the Mayer-Vietoris seqnence for M = XuDn+lXSl. (The orientations of Sn +2 and K study

2-knots

determine canonical isomorphisms). We shall in fact

through

K

the

corresponding

closed

oriented

4-manifolds

M(K). There is however an ambiguity when we attempt

M(K). The cocore 'I

from

=

{O}XS 1

C

D n +lxS 1

to recover K

M of the original sur-

C

gery is well defined up to isotopy by the conjugacy class of a meridian in

=

"K

"I(M).

(In fact the orientation of 'I is irrelevant for what follows).

Its normal bundle is trivial, so r has a product neighbourhood, P say, and we may assume that

ax

ways of identifying phisms

SnxSl

of

reversed

the

M -int P = X.

that

jT:

we

obtain

a

across

construction

SnXD2,

of

M

If however we identify new

tw~ essentially distinct

SnxSl = iXS n XD 2 ), modulo

extend

original

(Xu jaSnXD2, Snx{O}). of

with

But there are

self homeomor-

n ;> 2.

provided

we

recover

SnxSl

If

we

(Sn +2, K) =

with X

pair (l:, K") '" (XUjT:SnXD2, Snx{O}).

by means By

van

Kampen's theorem l: is simply connected, and it is easily seen to have the homology of Sn+2. Therefore l: is homeomorphic to Sn+2. We may assume that

the homeomorphism is orientation preserving. Thus we obtain a new

n -knot K", which we shall call the Gluck reconstruction

of K. The knot

K is said to be reflexive if it is determined as an unoriented submanifold by its exterior, i.e. if K" is isotopic to K, rK, Kp or -K. By the work of Browder, Gluck and Kato, if n ;> 2 there are at most two n -knots (up to change of orientations) with a given exterior, i.e. if there is an orientation preserving homeomorphism from X(K 1) to X(K) then

Kl

is

isotopic

to

K, K", Kp

or

K"p.

If

the

homeomorphism

preserves the homology class of the meridians then K 1 is isotopic to K

also or

K". (The long-standing conjecture that each classical knot is determined up

to orientation by

its exterior has finally

been confirmed [GL 19881. The

Knots and Related Manifolds

5

argnment involves some of the deepest results of 3-manifold topology). Thus a knot K

is determined up to an ambiguity of order at most 2 by X(K),

or (if n ;> 2) equivalently by M(K) together with the conjugacy class of a meridian in 'irK. which are provided

not

Cappell and Shaneson gave reflexive

that certain

[CS

(n

the

first

19761. Their method

examples of

works

for

+l)X(n +1) integral matrices exist; at

knots

each n ;> 2 present

such

matrices have been found only for n = 2, 3, 4 and 5. Gordon gave a different

family

of examples when n = 2, all of which are

PL knots

with

respect to the standard triangulation of S4 [Go 19761. Covering spaces and equivariant homology We shall let X(K) and X'(K) denote the universal and maximal

abelian are

covering spaces (respectively) of X(K). Similarly

M (K)

M(K) and

the corresponding covering spaces of M(K). The fundamen tal group of ~

X' (and of M, provided that n

2) is the commutator subgroup

of the

'Ir'

knot group, and by the Hurewicz theorem 'lrl'lr' = H 1(X;Z) = Z. Thus

the

cover X'IX is also known as the infinite cyclic cover of the knot exterior. The

homology

and

cohomology

of

such

covering

spaces

are

modules over the group ring of the covering group, and satisfy a form of equivariant

Poincare duality.

generality.

Let

P

be

a

We

shall

closed

describe

orient able

this

in

somewhat

m -manifold

with

greater

fundamental

group G. Up to homotopy we may approximate P by a finite cell complex [KS: Essay 111.4]. Let H

be a normal subgroup of G

and let PH be the

corresponding covering space. We may then lift the cellular decomposition of

P

to an equivariant cellular decomposition of PH. The cellular chain com-

plex C.. of PH with coefficients in a commutative ring R plex of left

R [GIH l-modules with respect

is then a com-

to the action of the covering

group GIH. Moreover C .. is a complex of free modules, with a finite basis obtained

by

choosing

one

equivariant bomology module

lift of

P

of

each

cell

with coefficients

P.

of

R [GIHl

The is

the

i tb left

module Hi(P;R[GIH]) = Hi (C.. ), which is clearly isomorphic to Hi(PH;R) as an

R -module,

with

the

action

of

the

covering

group

determining

the

R [GIH1-structure. The i tb equivariant cobomology module of P with coefficients

R [GIHl

is

Hi(Hom R [GIH1(C.. ,R [GIH])),

the which

right may

be

module interpreted

Hi(P;R [GIH]) = as

cohomology

of

6

Knots and Related Manifolds

PH with compact supports. If N

module

with

is a

the

-modul~

R

underlying

ng- 1 for g in 0

=

determined by g.a

R [Ol-module we shall let N

right

same

and

the

denote

the left

0 -action,

conjugate

and n in N.

The equivariant homology and cohomology are related by Poincare duality isomorphisms HjCP;R[OIH)) = Hm-j(P;R[OIH» and by a Universal Coefficient spectral sequence with E2 term E~q

= Extj [GIHI (Hp(P;R [GIH»,R [GIH)) => HP+q(P;R [GIHD,

in which the differential d r has bidegree (l-r,r). If J is a normal subgroup of

0

which

contains

H

there

is

also

a

Cartan-Leray

spectral

sequence

relating the homology of PH to that of PJ ' with E2 term

E2 = TorR[GIHI(H (P·R[GIH))R[GIJ)) => H (P·R[OIJ» pq p q" p+q , in

which

the

dr

differential

has

bidegree

(-r,r-l).

There

are

similar

definitions and results for manifold pairs (p,ap) and for (co)homology with more

general

coefficients

[WI.

For

more

information

on

these

spectral

sequences see [McC). When

K

is

an

P = X(K)

n -knot,

MCK),

Or

0

TrK

=

and

Tr', the group ring Z [TrITr'1 is the ring of integral Laurent polynomials Z[ZI = Z[t,t- 1 1. Since A is noetherian the homology and cohomology

H A of a

finitely

generated free

A-chain

The augmentation module Z free

resolution 0 -

A -

complex are

also

finitely

has projective dimension 1 as it has a short

A -

Z

o.

-

tral sequence for the projection of X'

Therefore onto X

the Cartan-Leray spec-

(or of M

on to

M)

to a long exact sequence (the Wang sequence of the map X' -

Since

X

has

t -l:Hj(X;A) -

the

homology

of

a

circle,

it

follows

tha t

reduces

X):

all

the

maps

H j (X;1\) are surjective for i > O. Therefore they are bijec-

tive (since

the modules are noetherian) and so

all

A-modules.

torsion

generated.

In

particular

the homology

modules are

Hom A(Hp(X;A),A) = 0 for

all p

so

the Universal Coefficient spectral sequence collapses to a collection of short

Knots and Relaled Manifolds

7

exact sequences Ext ~(Hp_2(X;I\),I\) -

o

Ext ~(Hp_l(X;I\),I\) -

HP(X;I\) -

O.

(There are very similar results for H .. (M;I\». The infinite cyclic covering spaces X'

M

and

cally much like (n +I)-manifolds wi th boundary Sn

behave homologi-

and empty respectively,

at least if we use field coefficients [Mi 1968, Ba 1980). If H i (X;I\) = 0 1 E;; i E;;

for

(n

then X'

+1)/2

homotopy equivalent

is acyclic; thus

to SI and so K

if also

is trivial. All

Z

=

Tr

then

is

X

the classifications of

higher dimensional knots to date assume that the knot group is Z

and that

the infinite cyclic cover of the exterior is highly connected. An n -knot K is

r-simple

called

if

X'(K)

is

it is simple.

[en -I)/2)-simple

r-connected;

if

~

n

3

and

the

knot

is

(The word is used in a different sense in

connection with classical knots). Levine classified simple (2q+1)-knots

with

q ;> 2 by means of Seifert matrices [Le 1970); this was reformulated (and reproven) in terms of the duality pairing on the middle dimensional homology by Kearton [Ke 1975). After Kearton and Kojima had each classified some

significant

subclasses of simple

2q -knots

with

q

~

4 by

analogous (but more complicated) pairings, Farber finished application of his classification of stable simple

for

1983).

By

some analogy

r

;> (n +1)/3)

with

guity by

the

classify all

might

with r ;> (n -1)/4 cohomology

I-simple knots

the

hope

of stable rational

that

an

to

homotopy

homotopy

r-simple

finite

pairings

of

in

K

to finite

(Ideally one might

ambiguity

[Fa

type of highly

n -knot

would be determined up

algebra H"(M(K);I\). up

means

task as an

n -knots (i.e. those which are r-

terms

results on

connected manifolds, one "formal range"

in

this

the

ambi-

hope

to

by algebraic invariants,

bu tit is not ye t clear wha t these should be). When n = 1 or 2 it is more profitable to work with the univer-

g (or ii>. When n = 1 the universal cover of

sal cover this

is

a

remarkable

dimensions X

result

of

Papakyriakopoulos

[Pa

X

is contractible;

1957).

In

higher

is aspherical only when the knot is trivial, as we shall see

in Chapter 2. Nevertheless under rather mild assumptions on the group of a 2-knot K

the closed 4-manifold M(K) is

aspherical. (See Chapter 3). This

is the main reason that we choose to work with M(K) rather than X(K).

8

Knots and Related Manifolds

Knot sums, factorization and satellites The sum of two n -knots Kl and K2 may be defined (up to isotopy) as

the

n -knot

obtained

K #K 2 l

as

follows.

D n (±) denote

Let

the

upper and lower hemispheres of Sn. We may isotope Kl and K2 so that each Ki(D n (±» is contained in D n +2(±), K 1(D n (+» is a D n +2 (+),

K (D n (-» 2

K 2 i Sn -1

(as

is

a

trivial

n-disc

the oriented boundaries of

trivial n -disc in

D n +2 (_)

in

and

Kli Sn-l

images of DO (-». Then we

the

let K #K 2 = K l iD n (-)uK 2 iD n (+). By van Kampen's theorem (used several l times)

1I"(K 1 #K 2)

erated

by

a

=

1I"K 1 "Z1l"K 2

meridian

in

where

the

knot

group.

each

amalgamating is

It

not

subgroup hard

to

is

gen-

see

that

X' (K 1 #K 2) is homotopy equivalent to X' (K l)vX' (K 2) and so in particular 1I"'(K 1 #K 2) = 1I"'(K 1)"1I"'(K 2)·

When

n = 1

this

construction

corresponds

to

tying

two

consecutively in the same loop. We say that a knot is irreducible

knots

if it is

not the sum of two nontrivial knots. Schubert showed that each I-knot has an

essentially

unique

factorization

as

a

sum of irreducible

irreducible

I-knots are usually called prime

dimensions

this

is

false

in

general.

shown that every n -knot with irreducible

knots,

length

of

such

needed

for

K

is

(i.e.

and

moreover

factorizations

their

argument

trivial

if

0

is

~

for

X(K)

However

Dunwoody

and

each

knot

19871.

As

criterion for SI),

it

there the

is

a

only

recognizing

applies

with finitely generated commutator subgroup

bound on

with more

terms

than

summands K j must have group Z For each n ;> 3 there factorizations

into

have

also

bound

then K

11"'

on

the

the

result

trivial knot

=

n

when

2,

by

is a 2-knot

has a finite factori-

the Gtushko-Neumann theorem places an upper

the number of nontrivial free

factorization

Fenn

geometric

Freedman's Unknotting Theorem. (It is easy to see that if K zation into irreducibles, for

In higher

3 admits some finite factorization into

[OF a

knots (and so

knots) [Sch 19491.

irreducibles

this

factors bound

of

11"'.

then at

If K least

is a

#Ki

one

of

the

and so be trivial). are n -knots which have several distinct

[BHK

19811.

Essentially

nothing

about uniqueness (or otherwise) of factorization when n = 2.

is

known

Knots and Related Manifolds

9

A more general method of combining two knots is the process of forming satellites. Although this construction arose in the classical case [Sch 19531, where it is intimately connected with the notion of torus decomposition, we shall describe only

the higher dimensional version of [Ka 19831.

Le t K 1 and K 2 be n -knots (with n > 1) and let 1 be a simple closed curve

X(K 1)'

in

with

a

product

homeomorphic to Sn xD 2 and so carries

Sn +2_ int U

onto

a

we

may

product

I:(K 2;K 1')') = bK 1 is called the We also call K 2 a companion

U.

neighbourhood find

a homeomorphism h

neighbourhood

satellite of K 1.

Sn +2-int U

Then

K 2.

of

of K 1 about

is

which

The

knot

K 2 relative

to )'.

If either r = 1 or K 2 is

trivial

then I:(K 2;K 1'") = K 1. The group of a satellite knot may be computed by means of van Kampen's Theorem (cf. Chapter 3). Fibred knots A Seifert bypersuriace for K sion 1 submanifold of Sn+2

is a locally flat, oriented codimen-

with (oriented) boundary

K.

By

a standard

argument these always exist. As we shall make little nse of Seifert hypersurfaces in this book, we shall only ontline the argument briefly. (We shall however use the phrase "Seifert manifold" below in the sense of closed 3manifold foliated that

p:X -

the

Sl

by circles).

Using obstruction

theory, it may

pr2j-l:aX(K) _ Sn xS 1 _ S 1

projection [Ke 1965).

By

topological

extends

transversality, we

be

to

shown a

may assume

map that

the inverse image p -1(1) is a bicollared, proper codimension 1 submanifold of X

[Ou 1982). The union p -1(1)Uj(Sn X[O,IJ) is then a Seifert hypersur-

face for K. If a 2-knot has a Seifert surface which is a once-punctured connected sum of lens spaces and copies of S1xS 2 then it is reflexive [01 19621. In general there is no canonical choice of a Seifert hypersurface. However there is one important special casco An n -knot K is fibred if we may find such a map p every

point of S 1

swept

out

by

is

copies

which is the projection of a fibre bundle (i.e. if a

of

regular the

value

Seifert

of p). The hypersurface

sphere obtained

Sn +2 from

is

then

p -1(1).

which are disjoint except at their common boundary K. The bundle is de te rmined

by

the

isotopy

class

of

the

characteristic

map,

which

is

a

self

10

Knots and Related Manifolds

e

homeomorphism FXeSl =

class of

of the fibre F of p.

Fx[O,II/-,

e

where (f ,0) '" (8({),1) for

is

P

the mapping

(n

f

in F.

The

isotopy

extends to a fibre bundle projection q:M(K) _ SI.

FuDn +1 of q

=

torus of

M(K) fibres over SI

an

all

is called the (geometric) monodromy of the bundle. It is easy to

see that such a map p The fibre

Indeed X(K) is the mapping torns

is called the closed fibre

the closed monodromy. Conversely, if n ;> 2 and

then we may assume that the characteristic map fixes

+2)-disc pointwise, and we see that K

=

is true when n

of K, and M(K)

is fibred. (An analogous result

1 [Ga 1987)). Many of our examples below shall arise as

a result of surgery on a simple closed curve in such a mapping torus. (For instance Cappell and Shaneson construct their pairs of distinct n -knots with homeomorphic

exteriors

by

starting

with

the

mapping

torus

of

a

self

homeomorphism of (SI)n +1). is fibred if and only if "' is free

A I-knot K

[St 19621.

In

high dimensions we may apply Farrell's fibration theorem to obtain a criterion for an n -knot with n ;> 4 to be fibred

[Fa 1970).

This applies

also when n = 3, provided the knot group is in the class of groups for which 4-dimensional surgery

and s -cobordism

theorems are known (cf. [Fr

1983)). Little is known when n = 2. It is conceivable

that

every 2-knot

whose commutator subgroup is finitely generated and torsion free may be fibred.

However

we

shall

show

in

Chapter

8

that

if

the

3-dimensional

Poincare conjecture is true then there are 2-knots whose commutator snbgroup is Z/3Z which are not fibred. If K 1 and K 2 are fibred

then so is their sum, and the closed

fibre of K 1 #K 2 is the connected sum of the closed fibres of K 1 and K 2' However in the absence of an adequate criterion for a 2-knot to fibre, we do not know whether every summand of a fibred knot is fibred. In view of the unique factorization that

there

would be

theorem for oriented 3-manifolds one might hope

a similar

theorem

for

fibred

2-knots. However

the

fibre of an irreducible 2-knot need not be an irreducible 3-manifold. (For instance a spun trefoil knot is an irreducible fibred 2-knot, but its closed fibre is S2xSl#S2XSl). No

nontrivial

2-knot

which

is

fibred

order is reflexive [PI 19861. (See also [HP 1988)).

with

monodromy

of

odd

Knots and Relaled Manifolds

11

Spinning and twist spinning The

first

nontrivial examples of higher dimensional

knots

were

given by Artin [Ar 19251. We may paraphrase his original idea as follows. As

the

half

R3

3-space

about the axis A

=

{

={

<w,x,Y,z> in R4: w = 0, z ;> 0

is

spun

} it sweeps out the whole of R 4, and any

arc in R3 with endpoints On A

sweeps out a 2-sphere. This construction

has been extended in several ways. If K

may choose a small (n+2)-disc Sn+2 n which meets K in an n-disc B such that (B n +2 , Bn) is homeomorphic to the

standard

is

pair.

the (Artin) spin

an n -knot, we

of K

is

=

(Sn+2-int B n + 2 , K-int B n ).

Then

the (n+1)-knot CT 1 K = i(Sn+2, K)oXD 2 ).

The

(n+p)-knot

This

p-superspin

of

makes sense

for any p ;> O. In particular, CTOK = K#-K. If p > 0 then

'lrCT pK

=

'irK.

K

(Sn+2, K)o

Let

is

the

CTpK = i(Sn+2, K)oXDP+1).

In general snperspinning is distinct from iterated spinning (cf.

rCa 1970)). Since the (p+l)-disc evidently has an orientation reversing involution, all p -snperspun knots are -amphicheiral. The p -superspin of a fibred knot is fibred, and the p -superspin of the sum of two knots is the sum o"f their p -supe rspins. For our purposes, another modification devised by 1966]) is of more construction. Let

I

interest. He

incorporated

Fox (cf.

[Fo

a

twist into Artin's original n be an integer and choose B +2 meeting K as above.

Then Sn+2-int Bn+Z = DnXDZ, and we may choose the homeomorphism so that

i(K - int Bn) lies in aDn x{O}.

Let

Pe be

the

self homeomorphism of

D n XD 2

that rotates the D2 factor through e radians. Then n n UPre(K-int B )X{8} is a submanifold of (Sn+2-int B +2)XS 1 homeomorphic to Dn xS 1 and which is standard on the boundary. Therefore

is an (n+1)-knot, called the I-twist spin of K. The O-twist spin is the Artin spin, i.e. r OK = of r I K

is obtained

from

power of (any) meridian

'irK

by

central.

adjoining

the

relation

Zeeman discovered

the

CT

1 K.

The group the

I tb

remarkable

fact

making

12

Knots and Related Manifolds

that

if

r

pOi

then

0

7: r K

is

with

fibred

geometric monodromy

order

of

dividing

r, and the closed fibre is the r-fold branched cyclic cover of Sn+2 , branched over K [Ze 19651. Hence 7:1K is always trivial. The rtwist spin of the sum of two knots is the sum of their r-twist spins. The twist

spin of a

-amphicheiral knot is

-amphicheiral, while

twist

spinning

interchanges invertibility and +amphicheirality [Li 19851. The 2-twist of any knot is reflexive [Mo 1983, PI 1984']. (More precisely, if K then K" trivial

the other hand, if r > 2 then no non-

is isotopic to rK). On

cyclic

branched

cover

of

spin

= 7:2k

an

r-twist

spin

of

a

simple

I-knot

is

reflexive [HP 19881. For other formulations and extensions of twist spinning see [GK 1978, Li 1979, PI 1984', Mo 1983, Mo 19841. In [Mo 19861 it is shown how to represent

twist

spins of classical knots

by means of hyperplane cross

sections (as in [Fo 1962, Lo 1981]). Slice and ribbon knots An n -knot K

is a slice

knot if there is an (n +l)-knot which

meets the equatorial Sn+2 of Sn+3 transversally in K; if the (n+l)-knot can be chosen

to be

trivial

then

K

is

K

is

doubly slice. As

Kervaire

showed that all even-dimensional knots are slice [Ke 19651, this notion is of little interest in connection with 2-knots. However not are

doubly

slice,

and

no

adequate

criterion

is

yet

all slice knots

known.

The

O-spin

uOK = K#-K of any knot K is a slice of the I-twist spin of K and so is doubly slice [Su 19711. An n -knot

K

is

a

ribbon

knot

if it

is

the

boundary of

an

immersed (n +1)-disc t:.. in Sn +2 whose only singularities are transverse double points, the double point set being a disjoint union of discs. All ribbon knots are slice.

It remains an open question as -to whether every slice 1-

knot is ribbon, but in every higher dimension there are slice knots which are not ribbon [Hi 19791. Given such a "ribbon" (n +1)-disc t:.. in Sn +2 the cartesian

product

t:..XDP

(n+l+p)-disc in Sn+2+p.

c Sn+2 XD P C Sn+2+p

determines

a

ribbon

All higher dimensional ribbon knots derive from

ribbon I-knots by this process [Ya 19771.

As the p-disc has an orienta-

tion reversing involution, this easily implies that all ribbon n -knots with

n

~

2 are -amphicheiral. The O-spin of a I-knot is a ribbon 2-knot. Each

Knots and Related Manifolds

13

ribbon 2-knot has a Seifert hypersurface which is a once-punctured connected sum of copies of S1XS2 and therefore is reflexive [Ya 19691. (See [Su 19761 for more on such geometric properties of ribbon 2-knots). An n -knot K is a homotopy ribbon knot if it bounds a properly embedded (n+l)-disc in D n +3 whose exterior W has a handlebody decomposition

consisting

M(K).

The

(n +1)-

dual

and

0,

1

and

decomposition

(n +2)-handles,

connected. (The [GK:

of

definition

Problem 4.221

2-handles. of

and

so

W

The

relative

the that

to

inclusion

of "homotopically

requires only

boundary

this

ribbon"

its of

of

is

W

boundary

W

Minto

for

I-knots

latter condition be

clearly

has

only

is

given

nin

satisfied).

Every ribbon knot is homotopy ribbon [Hi 19791. A nontrivial twist spin of a I-knot is never homotopy ribbon [Co 19831. (See also Chapter 3). Links Knot theory is the paradigm for the general problem of codimension 2 embeddings of connected manifolds in manifolds. Although we do not intend to stray far from our concentration on 2-knots, we shall occassionally point out where the resnlts described below may be extended to more general situations. In particular, similar questions arise in connection with the groups of links and of homology spheres, so we shall describe

these

briefly. A J.I.-component n -link is a locally flat embedding n ... Sn+2. It has exterior X(L) L:J.l.S Sn+2-LXint D2 and its group is

"L = "I(X(L». A link L is trivial if it bounds a collection of J.I. disjoint (n+l)-discs

in

Sn+2.

It

is

split

if each

of

its

components

lies

in

an

(n+2)-disc in Sn+2 which is disjoint from the other components, and it is a boundary link if it bounds a collection of J.I. disjoint orientable hypersurfaces in Sn+2. Clearly a trivial link is split, and a split link is a boundary link; neither implication can be reversed (if J.I. > 1). Each knot is a boundary link, and many arguments with knots that depend upon Seifert hypersurfaces extend readily to boundary links. The notions of slice and ribbon links are natural extensions of the corresponding notions for knots (cf. [H: Chapter II]). A J.I.-component n -link is a boundary link if and only if there is a homomorphism from "L to F(J.I.), the free group of rank J.I., which carries

14

Knots and Related Manifolds

a set of meridians (one for each component) to a free basis for F(Il); such a homomorphism can be realized by a continuous map from X(L) to vllS1, the wedge of Il circles. If n '" 2 the link is trivial if and only if this map is (n+1)/2-connected [Gu 19721. When n

2 the correct criterion for

=0

triviality is unknown: it is plausible that every Il-component 2-link whose group is

freely

generated

by

meridians

is

trivial. (The

condition on

the

meridians is necessary [Po 1974)). Also unknown is a good criterion for a 2-1ink to split, and whether every 2-link is slice. (Even-dimensional boundary n

links

> 1

are

and

always

more

slice

than

1

[Gu

1972]). The

component

exterior of

never

fibres

an

over

n -link

the

with

circle

[H:

Theorem VIlI.4]. Every ribbon n -link with n > 1 is a sublink of a ribbon link whose group is free [H: Theorem 11.1]. An homology m -sphere is a closed m -manifold with the integral homology of Sm. homology tunately (Theorem

More

Il ~ O.

Unforgroups

1 of

dimensional

links of

Kervaire's characterization of high. dimensional knot

m -spheres while

generally, we may consider Il-component

in

an

homology

Chapter 2) extends

link

groups,

a

crucial

(m +2)-sphere

readily

to

theorems in Chapter 3 below is that X(X(L» when Il = I, i.e. when

we

a

assumption

characterization of

in =

with

one

of

our

high

principal

0, which is only possible

are considering knots (in homology 4-spheres).

(We may instead propose the following less standard situations to which our methods

probably

extend

without

difficulty. These are when we consider embeddings of one or several tori SlXS 1 in S3 XS1 or SlXS1XS1XS1, or of pairs of 2-spheres in S2XS 2 ). For recent work on embeddings of other surfaces in S4, see [I:'i 1981, FKV 1988, Li 19881.

15 Chapter 2

THE KNOT GROUP Kervaire characterized

as

the

finitely

which are

presentable

the

groups of n -knots (for 0

groups

each n

~

01G' ;;; Z, H (0;Z) = 0 2

with

3) and

the normal closure of a single element [Ke 19651. These condi-

tions are also necessary when n

1 or 2, but are

then no longer suffi-

cient. The group of a nontrivial I-knot has geometric dimension 2 and has one end IPa 19571. The main concern of this book is with the intermediate case n = 2. In the

this case Kervaire showed also

above conditions has deficiency

1

then it

that if a group satisfying is

the group of a

2-knot.

However not every 2-knot group has deficiency 1. Subsequently several people observed independently and approximately simultaneously that not every high dimensional knot group is a

2-knot

group. Their arguments all

used

duality in the infinite cyclic cover of the exterior of the knot. In

this

chapter

we

shall

review

their extensions and applications. In

these

results

and

various

the next chapter we shall show

of that

by using duality in more general covering spaces we can get much stronger results.

Kervaire's conditions If S is a subset of a group 0

normal closure tains S. The

of S

we shall let «S»O denote the

in 0, the smallest normal subgroup of 0

which con-

weigbt of a group is the minimum number of elements in a

subset whose normal closure is the whole group. If 0 is an element such that «g »0 '"' 0

has weight 1 and g

we call g

then

a

weight element

for 0, and its conjugacy class a weight class for O. As the group " of an n -knot K compact

(n +2)-manifold

it

H 1(X;Z) ;;; Z

and

theorem)

H 2(";Z) = 0

and

is

finitely

o.

H 2(X;Z)

is the fundamental group of a

presentable.

Therefore

(since

it

is

"I"'

the

By

Alexander

;;; Z

cokernel

duality

(by

the

Hurewicz

of

the

Hurewicz

homomorphism from "2(X) to H 2(X;Z), by a theorem of Hopf [Ho 1942]). Moreover " has weight I, for if J.I. is a meridian, represented by a simple closed curve on

ax

then X UJlD 2 is a deformation retract of Sn+2_{o} and

so is simply connected. (Alterna tively X

bounds

a

singular

disc

in

Sn+2

we may observe which

may

be

that

any loop "'I in

assumed

to

meet

K

16

The Knot Group

transversely in finitely many points; "I is then homotopic in X to a product of

conjugates

of

meridians, bounding

Kervaire showed

transverse

discs

near

that, conversely, any group satisfying ~

the group of some n -knot, for each n

3.

these

points).

these conditions is

In fact it is sufficient

"U pK

show that each such group can be realized by a 3-knot, for

to

= "K

for all p > 0, and so we may call such groups 3-knot groups. Theorem 1 [Ke 19651 A group G is a 3-knot group if and only if it

is finitely presentable, G/G' ~ Z, H 2(G;Z) = 0 and G bas weigbt 1. Proof The conditions are necessary, by the above remarks. Let P be a finite presentation for G, with g generators and r relators, and let C(P) be the corresponding 2-dimensional cell complex, with one O-cell, g I-cells and r

2-cells. For each n ~ 2 we may embed C(P) in R n +3. Choose such an

au

embedding and let U be a regular neighbourhood of the image. Then a closed s -parallelizable (n +2)-manifold, and the inclusion of an

n -connected

map,

since

=

"I(C(P» = G

Since

C(P)

a

finite

free

abelian to

"2(aU)'

is of

finite

codimension

2-dimensional complex

onto

n +1

into U is

U.

Therefore

in

and Hk(aU;Z) = Hk(C(P);Z)

rank. Since is

H 2(aU;Z)

has

C(P)

"l(aU) = "I(U)

[Ho

19421.

k C; n.

for

H 2(aU;Z) = H 2 (C(P);Z)

H 2(G;Z) = 0

the

Hurewicz map

Therefore

if

n

is

au

~

3

we

is

from can

represent a basis of H 2(aU;Z) by embedded spheres, which have trivial normal

bundles

as

au

is

s-parallelizable.

spheres we obtain a closed orientable group G

(since

of

Sn+lxS I .

"I(V) ~ G,

sphere, which is

performing

+2)-manifold

V

the surgered spheres have codimension n

has the homology of element

On

(n

we

surgery

on

these

with fundamental ~

3), and which

If we now perform surgery on a weight

obtain

therefore Sn +2 by

a

simply

the

connected

homology

(n+2)-

validity of the high dimensional

Poincare conjecture, and which contains an n -knot (the cocore of the surgery) with group G. 0

The only points at which the high dimensionality was used were where

we

wished

to

use

surgery

to

kill

H 2(aU;Z),

while

retaining

"I(V) ~ G, and when we invoked the high dimensional Poincare conjecture.

17

The Knot Group

The following extension to the case n = 2 is due to Kervaire, apart from the appeal to the subsequent work of Freedman. (Recall that if P is a fingenerators and r

ite presentation of G, with g

relators,

then the defi-

ciency of P is deE P = g - r, and deE G is the maximal deficiency of all finite presentations of G). If G satisEies the hypotheses of

Addendum [Ke 19651

Theorem 1 and

also has a presentation of deficiency 1 then G is a 2-knot group. Proof

/J

Let

be

1-g+r

I-deE P.

H 2 (aU;Z)

=

the

rank

of

H 2 (aU;Z).

/J

Then

1-1+/J = X(C(P»

=

Therefore def P .;;; I, and def P = 1 if and only if

O. In the latter case we do not need to surger any 2-spheres.

Since there is no difficulty in surge ring I-spheres in dimension 4, and since the 4-dimensional (TOP) Poincare conjecture is true [Fr 19821, the above construction gives a knot in S4. 0

It may be shown that any 3-knot group with a presentation of

deficiency 1 is in fact such

a

presentation

D5 u {h />U{h

J}

2-handle" h topy

5-ball

sphere, and

the group of a homotopy ribbon 2-knot, by using to

construct

a

5-dimensional

handlebody

with 11"1 (aW) = "1 (W) ~ G and X( W) = O.

W =

Adjoining another

along a loop representing a weight class for G gives a homoB

with

I-connected

boundary.

Thus

aB

is

a

the boundary of the cocore of the 2-handle h

homotopy

4-

is clearly a

homotopy ribbon 2-knot with group G. It is easy to see that if deE G = 1 then weight G

1 implies

that G/G' ~ Z, and that G/G' ~ Z

implies that H 2(G;Z) O. The con0 and weight G = 1 are otherwise indepen-

ditions G/G' ~ Z, H 2(G;Z) = dent. (For instance, Z-SL(2,5) satisfies

the first

two conditions, but does

not have weight 1 [GR 19621; if G is the (metabelian) group with presentation (i.e. the group of the closed 3manifold

obtained

by

O-framed

surgery

on

the

trefoil

knot)

then

has weight I, but H 2(G;Z) ~ Z, and any finite cyclic group satisfies the last two conditions but not the first). G/G'

Z

and G

If G is a group with G/G' ~ Z

and deficiency 1 then the first

nonzero elementary ideal E 1(G) is principal, and so G' /G"

is torsion free

18

The Knot Group

(cf. Chapter IV of [H», Therefore the group of the 2-twist spin of the trefoil

knot

does not

have deficiency

I, for

it

bas commutator subgroup

cyclic of order 3. Thus the deficiency condition is too stringent in general. Kervaire gave analogous characterizations of the groups of high dimensional links and homology spheres. As the proofs are similar to that of Theorem 1 we shall just state his results. Theorem

A

[Ke

A group G is tbe group of all-component 3-

1965'1

link if and only if it is finitely presentable, G/G' ~ ZIl, H 2(G;Z) = 0 and G bas weigbt Jl, If moreover G bas a presentation of deficiency Il tben it is tbe group of all-component 2-link. 0

The

G

group

of

a

Il-component

I-link

has

Il

weight

and

G/G' ~ ZJ1., but H 2(G;Z) is only 0 (eqnivalently, def G = J1.) if the link is completely splittable [H: Theorem 1.21. If we combine Theorem A with Gutierrez' characterization of high

dimensional boundary links [Gu 19721 we find that the groups of such links are distinguished by

the additional condition that

G maps onto F(Il),

the

free group of rank J1., with a set of weight elements for G mapping to a free

basis

for

F(Il).

If

we drop

the condition on

the

weight

of G

in

Theorem A we obtain a characterization of the groups of links of Il nspheres in homology (n+2)-spheres (for Il

Theorem

B

[Ke

0). In particular we have

A group G is tbe group of an bomology

1969]

m -spbere (for eacb m

~

~

5) if and only if it is

finitely presentable,

G = G' and H 2(G;Z) = o. If moreover G bas a presentation of deficiency 0 tben it is tbe group of an bomology 4-spbere. 0

Theorem B is easier in so far as there is no need to appeal to the b -cobordism theorem (in order to recognize the standard sphere). Little else is known about the gronps of homology 4-spheres. There are many finite perfect groups with presentations of deficiency O. (Note that a perfect

G

group

Hi(G;Z) or q

=

with

a

0 for i

presentation

=

of

deficiency

0

is

superperfect,

1 and 2). For instance the groups SL(2,q) for q

i.e. =

8

a power of an odd prime (q '" 3) are examples of such groups [CR

The Knot Group

19

1980]. It

is not known whether deficiency 0 is a necessary condition. In

particular

can

I-Xlis

1- = SL(2,5)

the

be

the

binary

group

of

an

homology

icosahedral group? (Note

4-sphere,

that

is

j-

where

the

only

finite group that is the group of an homology 3-sphere). The more general manifolds of

V

V

problem of codimension 2 embeddings of n-

in Sn +2 does not lead to new groups unless some component

has nontrivial

first

homology, since Hi(Sn +2_ V;Z)

i = 1 and 2, by

Hi -1 (V;Z) for

is

isomorphic to

Alexander duali ty in Sn +2 and

Poincare

duality in V.

The commutator snbgroup In our later arguments we shall often first identify the commutator subgroup "' of a knot group ", and so we shall reformulate the Kervaire conditions. We say that an automorphism of a group G is meridia-

na} if «g-l(g)lg in G»G = G.

If H

is a characteristic subgroup of

G

then clearly induces a meridianal automorphism of the quotient GIH.

In

particular

the

induced

endomorphism

H 1( O.

Now

H 2(7r';Z)

is

the

cokernel

of

the

Hurewicz map from 7r 2(X') to H 2(X';Z), which commutes with the action of the covering group, and so multiplication by t-l gives an automorphism (namely H 2 (6)-I) of H 2(rr';Z) also. Conversely any such group " has weight I, abelianization Z, and on applying the Wang sequence for the projection of K(rr',I) onto K(7r,l) we find that H 2 (7r;Z) = 0, and so 7r is a 3-knot group. 0

Hausmann and Kervaire have expressed the condition that 7r'X(JZ be

finitely

presentable

in

terms

of

7r'

having

a

"finite

Z -dynamic

The Knot Group

21

presentation" [HK 19781. When "' is an abelian group A

the condition that the automor-

=

phism be meridianal reduces to the action of t -Ion A

HI (A;Z) being

invertible. Moreover in that case the group H 2(A;Z) may be identified with the

AAA

exterior product

[R: page

3341. Levine

and

Weber have

made

explicit the conditions on the pair (A,!) in the following way [LW 1978]. If A

let t.O(A) be

is a finitely generated A-module

the highest common

factor of the ideal EO(A) in A, and for each prime p let t.(A. Then "' is cyclic of order 5, t-l

acts as the identity and H 2("';Z) = 0, so " is a 3-knot group. However it is easy to see that if I( , ) is any nondegenerate Z -bilinear pairing on "'

26

The Knot Group

with values in Q/ Z

then Jet a.,t p) = 4/(a.,p) = -J(a.,P) for all a.,p in rr'. Thus

t cannot be an isometry and so rr is not a 2-knot group.

Centres

Since the commutator subgroup of a classical knot

group rr can

contain no nontrivial abelian normal subgroup [N: Chapters IV,VI, any nontrivial abelian normal subgroup of rr must map injectively to rr/rr' = Z

and

so be central. Burde and Zieschang have shown that in fact the knot must then be a torus knot [BZ 19661. In high dimensions the situation is quite different. Hausmann and Kervaire have shown that every finitely generated abelian group A centre of some n -knot group, for each n that

if P

is a

finitely

presentable

~

3 [HK 1978'1.

superperfect group and

is the

They observe G

is a

knot

group then by the KUnneth theorem Hi(GXP;Z) = HlG;Z) for i " 2, and

If moreover there is an c1ement P in

GxP has centre ((G XP) = CG XCP. P

such that the subgroup [p,PI generated by {(p,xl = pxp- 1 x- 1 :x in P}

is

the

weight

whole of P, and if g element

for

erally if P l' in

Pi

Pi)

CG (i)CP 1(i).

it

shall

then

which is

GXP, Pr

is a weight element

are

r

GXP 1 X

therefore a

for G, then gp

3-knot

group.

is a

More gen-

such superperfect groups (with such elements is

. . xP r

a

3-knot

group

with

centre

. (i)CP r" Thus to obtain the result of Hausmann and Kervaire

suffice

to

take

G

to be

a

knot

group

with

trivial centre (for

instance the group of the figure eight knot) and to show that each cyclic group is the centre of some such group P. For the infinite cyclic group we may take P to be the fundamental group of a suitable Brieskorn homology 3-sphere, for instance the group with presentation , with p may

use

the element represented by a. For the cyclic group of order 2 we I" = SL(2,5) (which

3-sphere), with p

is also

the group of a

Brieskorn homology

any noncentral element. If k :> 3 and F

is any finite

field containing k distinct k tb roots of unity (other than F 4) then SL(k,F) is a finite superperfect group (cf. [M: pages 78,94» with centre cyclic of order k; we may take p in

to be the elementary matrix e £2 (with entry 1

the (1,2) position). Hausmann and Kervaire gave more general construc-

tions and showed that each such A groups.

is the centre of infinitely many 3-knot

The Knot Group They left open the questions as to whether the centre need hI finitely

generated,

Chapters 3 and

and

4

we

what

the

centre

shall show

that

of

a

2-knot

the centre

group

of a

may

2-knot

In

be.

group i.

either torsion free of rank 2 or has rank at most 1. CExamples are known with centre Z2, Z(i)CZ/2Z), Z or Z/2Z). Whether the centre of a 2-knot group must be finitely generated is related to the analogous question for 3-dimensional Poincare duality groups, which seems difficult. ~

If FCp.) is a free group of rank p.

2, and if P l'

finitely presentable superperfect groups with elements Pi as above, then the group FCp.)XP 1 X (for each n

XP r

..•

is the group of a p.-componen t boundary n -link

~

3) with centre (i)CP i . Thus the centre of a p.-component nlink can be any finitely generated abelian group, if p. ~ 1 and n ~ 3. We

shall show p. > 1

in Chapter 3

that

the

centre

of a

p.-component

2-link

with

must be a torsion group.

MiDimizing the Euler characteristic We saw above that a 3-knot group " must satisfy certain homological conditions, notably H 2(";Z)

=

D, and

that if the stronger, combina-

torial condition del" = 1 also holds then " is a 2-knot group. Analogous situations arise in attempting to characterize the groups of 2-links, homology 4-spheres etc. Now every finitely presentable group is the fundamental group of some closed

orient able

4-manifold. Thus

we

may define

a

new

invariant which may help bridge the gap between necessary homological and sufficien t combina torial conditions by qCG)

=

min{XCM)\ M a closed orientabJe 4-maniloJd with "lCM)

=

G}.

Hausmann and Weinberger observed that this invariant is well behaved with respect to subgroups of finite index, since the Euler characteristic is multiplicative in finite coverings, and it is this property that makes qC ) useful. For any space number of fJiCKCG,1);F).

Theorem 4

M

and

M

with coefficients

field F,

and

F

Ie t

for

PiCM;F) be

any

group

G

the

i th

let

PiCG;F) =

Then we have the following estimates.

[HW

1985]

2(1-P1(G;F»+P2(G;F)

~

Let G be a q(G)

~

finitely presentable group.

2C1-del G).

Then

Be tti

28

The Knot Group

Proof Le t

be

M

HI(GjF)

and

manifold

then

any

space maps

H (MjF) 2

by

with

fundamental

onto

If

H (GjF). 2

Poincare duality

group G. Then HI (MjF) =

X(M) =

is

M

an

orientable

4-

These

2(I-PI(M;F»+P2(M;F).

two observations give the first inequality. If P is a finite presentation for G and C(P) is the correspond-

ing 2-complex then we may embed C(P) in R S. regular

neighbourhood

is

=

lTI(V) = G and X(V)

then

a

Proof If M

V

of a

4-manifold

with

2(1-def G), and so we get the second inequality. 0

Coronary Let H be a subgroup which has 2(I-PI(HjF»+P2(HjF) "

The boundary

s -parallelizable

closed

finite index in G. Then

[G:H]q, in

presen ta tion which

each

of

the

relation

form

asserts

the

conjugacy of two of the generators. In this section we shall examine some of the connections be tween these properties. Since the Artin spin of a I-knot is a ribbon 2-knot every 1knot group is the group of some ribbon 2-knot. By an elementary handle sliding argument it may be seen that any ribbon

D

-link (with

D

~

2) is a

sublink of a ribbon link whose group is free [H: Theorem 11.11. It follows that the group of a J.I-component

ribbon

inger) presentation of deficiency J.I,

D

-link (with

knots

[Ya

1969]). Conversely

any

(ribbon)

D

group

(n+3)-manifold

of

the group has

the groups of ribbon 2-

weight

J.I

with

the group of a J.I-component

-link with group free, for each

the group of a homotopy ribbon

:> 2) has a (Wirt-

which is optimal, since

weight J.I. (This was first proven by Yajima for presentation of deficiency J.I is

D

D

D

~

-knot (with

a

(Wirtinger)

sublink of a

2 [H: Theorem 11.31. Since D

~

2) is

the group of a

W which can be built with 0-, 1- and 2-handles only and

which has Euler characteristic 0, such groups also have deficiency l.

30

The Knot Group

Levine

showed

that

if 7r

has

a

presentation

P

such

that

the

presentation of the trivial group obtained by adjoining the relation killing a meridian to P is AC-equivalent

to the empty presentation then 7r is

group of a smooth knot in the standard 4-sphere.

the

According to Yoshikawa,

7r has such a presentation if and only 'if it has a Wirtinger presentation of deficiency 1 [Yo 1982'].

(See also lSi 1980] for connections between Wirt-

inger presentations and the condition that H 2(7r;Z) = 0). A group has (finite) geometric dimension

2 if it is the funda-

mental group of a (finite) aspherical 2-complex, but is not free. Every such group has cohomological dimension 2. It is an open question as to whether every (finitely presentable) group of cohomological dimension 2 has (finite) geometric dimension 2 (cf.

[W': Problem D.4D. The following partial answer

'to this question was first obtained by Beckmann under the further assumption that G has type FL (cf [Dy 1987']).

Theorem

6

Let G

be a

finitely presentable group.

Then

G

has

finite

geometric dimension 2 if and only if it has cohomological dimension 2 and deficiency Pl(G;Q)-P2(O;Q).

Proof Let P and let

be a presentation for G

C(P) be

the

with g

generators and r

relators,

corresponding 2-complex. Then def P = l-X(C(P»

PI (C(P>;Q)- P2 (C(P);Q) "

PI (O;Q)- P2(O;Q),

and

the

=

necessi ty of the condi-

tions is clear. The cellular chain complex of the universal cover C(P) may be

viewed

as a

finite

chain complex of free

left

Z[G)-modules, and so

there is an exact sequence

o -

L

ZIG]g

= 7r 2(C(P»

As c.d.G = 2, the image of Z[G]r lemma. Therefore the inclusion of L Since

c.d.G = 2,

the

in Z[G]g

ZIG] -

Z

is projective, by Schanuel's

into Z[G]r splits, and L

Hattori-Stallings

rank

O.

of L

is projective.

is concentrated on

the

conjugacy class of the identity [Ec 1986], and so the Kaplansky rank of

L

is

Q~Z[G]L

the

dimension

=

0 and so L

of

=

Q~Z[G)L.

If def P = Pl(G;Q)-P2(G;Q)

then

0, by a theorem of Kaplansky. (See Section 2

of [Dy 1987] for more details on the properties and interrelations of the various notions of rank). Hence C(P) is asphericaJ. 0

31

The Knot Group

Suppose now that G has weight p. and a presentation P of deficiency

and

p.,

obtained

by

Ie t

adjoining

element subse t

be

CCP)

G

of

the

corresponding

2-cells

f.J.

whose

to

2-complex.

along

CCP)

normal closure

is

loops

the

The

2-complex

representing

whole

a

p.-

group is simply

connected and has Euler characteristic 1, and so is contractible. Therefore if the Whitehead conjecture is true the subcomplex CCP) must also be aspherical, and so G

is

free or has finite

geome tric dimension 2. (In particular,

this is so if G is a I-relator group Ccf. [Ly 1950, Go 1981)), or is locally indicable [Ho 19821 or if it has no nontrivial superperfect normal subgroup [Oy 1987)).

Thus Theorem 6 and the

Whitehead conjecture together imply

that a 3-knot group has finite geometric dimension 2 if and only if it has deficiency 1, in which case it is a 2-knot group.

If the commutator subgroup of a 2-knot group Tr with deficiency 1 is finitely generated must it be free? This is so if Tr is a classical knot group [N: Theorem 4.5.11 or if c.d.Tr = 2 and Tr' is almost finitely presentable [B: Corollary 8.61.

Sphericity of the eJ:terior The

oustanding property

of

the

exterior of a

classical

knot

is

that it is asphericaJ. In contrast, the exterior of a higher dimensional knot is aspherical only when it has the homotopy type of a circle, in which case the knot must be

trivial [OV 19731. The proof that we shall give is due

to Eckmann, who also showed that the exterior of a higher dimensional link with more than one component is never aspherical [Ec 19761.

(The exterior

of a I-link is aspherical if and only if the link is unsplittable).

7

Theorem

such

1973, Ec

19761

that X(K) is aspberical.

Proof

Let

there

Therefore through

i:aX -

Z

Tr 1CaX)

i.e.

[OV

X

be

and since X

are the

maps map

Hn+l CS 1ih#Z[TrJ)

HD+1CX,aXiZ[TrJ) -

K

is

natural

trivial.

inclusion.

is aspherical i S1

j:ax i#

Then

the

be an n -knot, for some n > 1,

Let K

from and

and

factors

h:S 1 _

HD+1(XiZ[Tr))

so

is

the

H1CXiZ[TrJ) = H1CXiZ)

0

X

to

Since

n

> 1

we

have

through S 1 = KCTr 1CaX),I), with

i

homotopic

H n + 1C8X;i" Z[Tr])

map.

By

Poincare

to

hj.

factors duality,

0, and so Hn+1CXiZ[TrJ) =

o.

32

The Knot Group

By Poincare duality again, H 1(X,oX;Z[IT» - 0 and so HO(oX;i" Z[IT» maps isomorphically to HO(X;Z[IT». But this means that the induced cover of ax is connected and so i.:1T 1(oX)

-+

1T

1(X) is onto. Therefore

IT

and so

Z

-

X '" Sl, since it is aspherical. The theorem now follows from the unknotting criterion. 0

Both Dyer and Vasquez and Eckmann prove somewhat more general results. Eckmann also observes that the full strength of the auumption of asphericity is not needed for

the above theorem. Together [Sw 1976]

and [Du 1985] imply that if in:1Tn (aX)

-+

IT

n (X) is the 0 map then

K

must

be trivial. In

the

M(K) obtained by

such a

knot

next

chapter

we

shall

show

that

the

closed

manifold

surgery on a 2-knot is often aspherical. The group of

has one

end; however Gonzalez-Acuna

and

Montesinos have

given examples of 2-knot groups with infinitely many ends, of which the simplest has presentation [GM 1978]. (This group is evidently an HNN extension of the metacyclic group generated by

{a ,b}

; it may also be viewed as the free product of

an isomorphic metacyclic group with the group of the 2-twist spun trefoil knot, amalgamated over a subgroup of order 3). Weight elements, classes and orbits

Two knots K and K 1 have homeomorphic exteriors if and only if there is a homeomorphism from M(K 1) to M(K) which carries the conjugacy class of a meridian of K 1 to that of K (up to inversion). In fact if M is any closed orientable 4-manifold with

X(M)

'"'

0 and with

IT

-

1T 1 (M) of

weight 1 then surgery on a weight class gives a 2-knot with group Moreover, if t and u are two weight elements and f

IT.

is a self homeomor-

phism of M such that u is conjugate to f .. (t±1) then surgeries on t and u lead to knots whose exteriors are homeomorphic (via the restriction of a self homeomorphism of M isotopic to

f).

Thus the natural invariant to dis-

tinguish between knots with isomorphic groups is not the weight class, but rather the weight orbit: the orbit of a weight element under the automorphisms of the group.

The Knot Group

33

A refinement of this notion is useful in distinguishing between oriented knots. If w is a weight element for

{"(w):,, in Aut(7T), ,,(w) ... w mod

7T'}

then we shall call the set

7T

a strict weight orbit for

A strict

7T.

weight orbit determines a transverse orientation for the corresponding knot (and

its

Gluck

recons truction).

An

orien ta tion

determined by an orientation for M(K). If K

for

the

ambien t

sphere

is

is invertible or +amphicheiral

then there is an orientation preserving (respectively, orientation reversing) self homeomorphism of M

which reverses the transverse orientation of the

knot, i.e. carries the strict weight orbit -amphicheiral

there

is

an orientation

to its inverse. Similarly, if K

is

reversing self homeomorphism of

M

which preserves the strict weight orbit. Theorem 8

Let G be a group of weight 1 with G/O' ~ Z, and let

be an element of G whose image generates G/O'.

For each g in G let

cg be the automorphism of 0' induced by conjugation by g.

Then

weight element if and only if c t is meridianal; (ii) two weight elements t, u are in the same weight class if and only if there is an element g of G' such that C u - Cg C t Cg- 1; (iii) two weight elements t, u are in the same strict weight orbit if only and if there is an automorphism d of 0' such that C = dc d- 1 u t and d c t d- 1c t-1 is an inner automorphism; (i)

t is a

(iv)

if

t and u are weight elements then u is conjugate to (g"t )±1

for some g" in 0". Proof The verification of (i-iii) is routine. If t and u are weight elements then, up to inversion, u must equal g't

0". Let g"

for some g' in 0'. Since t -1 acts

we have g' = khth -1 t -1 for some h in 0' and k in

invertibly on 0'/0"

- h -1kb . Then u = g't = hg"th -1. 0

An immediate consequence of this theorem is that if t are in the same <Strict weight orbit then c

and u

u have the same order, t and their images in Out(O') are equal. Moreover if C is the centralizer of

ct

in

Aut(O')

then

II(Aut(G' )/Clnn (0'»

~

the

strict

weight

IIOut(O') weight

and

orbi t

classes.

C

of In

contains general

infinitely many weight orbits [PI 1983'). However, if

7T

there

at

most

may

is metabelian

be the

34

The Knot Group

weight class (and hence the weight orbit) is unique up to inversion, by part (iv) of the theorem. Fibred 2-knots

Many of the

most

interesting examples arise

from 4-manifolds

which fibre over the circle; the knots are then fib red knots. The counter example of Farber given above shows that some restriction on torsion is needed for the next result. Theorem

9

Let

71'

be a

torsion

free 3-knot group such that rr' is the

fundamental group of a closed orientable 3-manifold N whose Haken, hyperbolic or Seifert

fibred.

Then

71'

is the group of a

factors are fibred

2-knot with closed fibre N. Proof Let N = P#R where P is a connected sum of copies of SlXS 2 and R

has no such factors. The meridianal automorphism of rr' ~ 71'l(N) may be

realized by a self homotopy equivalence g of N ting Theorem of [La 19741, g

[Sw 19741. By the Split-

is homotopic to a connected sum of homo-

topy equivalences between the irreducible factors of R

with a self homo-

topy equivalence of P. By our assumptions, these maps are homotopic to homeomorphisms.

(Cf. [Wa 1968, Mo 1968, Sc 19831 and [La 19741 respec-

tively). Thus we may assume that g is a self homeomorphism of N. Surgery on a weight class in the mapping torus of g closed fibre N and group

71'.

gives a fibred 2-knot with

0

Since N is determined by rr' and homotopy implies isotopy if N is a connected sum of Haken manifolds and copies of SlXS 2 [La 19741, or is hyperbolic [Mo 19681 or Seifert fibred [Sc 1985, BO 19861, the mapping torus of g

is unique up to homeomorphism among fibred 4-manifolds with

such a fibre. The r-twist spin of a i-knot K

is a fibred 2-knot, and

factors of its closed fibre are Haken, hyperbolic or Seifert fibred.

the With

exceptions for small values of r, the factors are aspherical, and 2 SlxS is never a factor. (See Chapter 5 for a more precise statement).

some

3S

The Knot Group

If

the

group

H 2(rr';Z) == 0

and

so

71'

the

of

a

closed

fib red fibre

S1xS 2 with a homology 3-sphere.

nected if and only if

71"

is

2-knot a

has

deficiency

1

then

connected sum of copies

of

The homology 3-sphere is simply con-

is free. Cochran has shown that if the closed fibre

is #r(S1XS2) the knot is homotopy ribbon, and that conversely the closed fibre of a fib red homotopy ribbon 2-knot is a connected sum of copies of S1XS 2 with a homotopy 3-sphere [Co 1983]. For fibred ribbon knots this follows from an argument of Trace. If V an n -knot K

q of

is any Seifert hypersurface for

then the embedding of V in X extends to an embedding of

== VuDn +1 in M, which lifts to an embedding in M'. Since the image

V

H n +1(M;Z)

in

is

Poincare

dual

to

Hom(7I',Z) == 1M,S1], its image in H n +1(M';Z)

fibred

is homotopy

M'

degree 1 map from

equivalent

to

a

generator

of

H 1(M;Z)

is a generator. If K

Z

the closed

fibre

P,

so

there

is

is a

q to P and hence to any factor of P. If moreover

n == 2 and 71'1(V) is free then each prime factor of

II

must be S1xS 2 or

a homotopy 3-sphere, by Lemma 1 of [Tr 19861. In particular, since ribbon 2-knots have such Seifert hypersurfaces no nontrivial fibred ribbon 2-knot is a twist spin. Ruberman has used a similar idea

together with the fact

that

the Gromov norm of a 3-manifold does not increase under degree 1 maps to show

that no fib red 2-knot with closed fibre

can have a Seifert hypersurface 1987].

(In

particular,

q

V

cannot

such that be

a

q

a hyperbolic 3-manifold is a graph manifold [Ru

Seifert

fibred

3-manifold

or

,r(S1XS 2». He also observes that the "Seifert volume" of Brooks and Gold-

man [BG 1984] may be used in a similar way to show that some fib red 2-knots

whose closed fibre

ribbon knots.

has an SL(2,R )-geometric structure cannot be

36 Chapter 3

LOCALIZATION AND ASPHERICITY Although the exterior X(K) of a nontrivial 2-knot K

is never

aspherical, in many cases the closed 4-manifold M(K) is aspherica!. so for instance if K

This is

is one of the Cappell-Shaneson knots, or (with fin-

itely many exceptions) if it is the q -twist spin of a prime classical knot for some q > 2. In this chapter we shall show that this is true whenever the knot group has a nontrivial torsion free abelian normal subgroup and is cohomologically

i-connected at

latter condition might

fail).

infinity.

The

knot

(We shall group

is

also consider how

then

a

the

Poincare duality

group of formal dimension 4 and orientable type, or PDt-group for short. (We

shall

also

show

that,

conversely,

if

is

TrK

a

PD 4 -group

and

H 1(Tr';Z /2Z) '" 0 then it is orient able and M(K) is asphericaD.

Our argument is based on the idea of embedding the group ring in

Z[Tr]

a

larger ring

R

in which

an

annihilator

for

the

augmentation

module becomes invertible and for which nontrivial stably free modules have well defined strictly positive rank, with duality

and

the

cohomological

having rank

RD

condition

on

Tr

we

D.

then

Using Poincare find

that

the

equivariant homology with coefficients R of a closed orient able 4-manifold wi th group

is concentrated in degree 2 and is stably free

Tr

as an R-

module. Its rank may then be computed by an Euler characteristic counting argument. When

Tr

has a nontrivial torsion free abelian normal subgroup the

existence of such an overring is guaranteed by a remarkable lemma of Rosset [Ro 1984]. This strategy works in considerably greater generality, provided we

forgo

groups

some

have

information

abelian normal

about

torsion.

subgroups,

For instance, although

there

may

be

finitely

solvable

presentable

infinite solvable groups in which no such subgroup is torsion free. In order to get around this problem we may factor out the maximal locally-finite normal subgroup. (This idea is due to Kropholler). The quotient of a 2-knot group by such a subgroup is then usually a PDt-group over Q.

Rosset's Lemma The keystone of the argument of this chapter (and hence of the whole book) is the following lemma of Rosset.

Localinlion and Asphericity Lemma

[Ro

198.. )

I"

Let G be a group witb a

torsion

free abcliu

normal subgroup A, and let S be tbe multiplicative system Z[A]-{O}

In

ZIG]. Tben tbe (noncentraJ/) localization R = S-1Z[G] exists and bas tbe property tbat eacb nontrivial finitely generated stably free R -module bas well defined strictly positive rank, witb R n baving rank n. Moreover R contains ZIG] as a subring, and is nontrivial tben RCj)Z[G]Z

The

prototype

=

flat as a Z[G]-module, and if A is

O. 0

of such

a

result

was

given

by

Kaplansky

who

showed that for any group G the group ring ZIG] has this strong "invariant basis number" property (cf. [K: page 122]). Rosset observes

that

the

mUltiplicative system S satisfies the Ore conditions (cf. [P: page 146]) and so the localization exists and is flat; if a

is a nontrivial element of A

then a -1 is in S and annihilates the augmentation module Z. Beyond this his

argument

follows

that

of

Kaplansky in making use

of properties

of

C· -algebras. (In [Hi 1981] we stated such a lemma for the case when A is central, and tried to derive it algebraically from Kaplansky's Lemma, but there was a gap in our argument). On the evidence of his work on 1-relator groups, Murasugi conjectured that the centre of a finitely presentable group other than Z2 of ~

deficiency

1 is infinite cyclic or trivial, and is trivial if the group has

deficiency > 1, and he showed that this is true for the groups of 1-links [Mu 1965]. (The classical knots and links whose groups have nontrivial centre have been determined by Burde, Zieschang and Murasugi [BZ 1966, BM 1970». As a corollary to our first application of Rosset's Lemma we shall show

that

a

stronger

conjecture

presentable groups, including all

is

true

for

a

large

class

of

finitely

those with a central element of infinite

order. Theorem

1

Let W be a

finite connected 2-dimensional cell complex sucb

tbat G = "l(W) bas a nontrivial torsion Tben X( W) Proof Let ture. Then

~

W

free abelian normal subgroup A.

0, and X( W) = 0 if and only if

W is aspberical.

be the universal cover of W with the equivariant cell struc-

the cellular chain complex of

W

may be

viewed as a

finite

38

LocaIization and Asphericity C2 -

chain complex of free left Z[G]-modules C. = 0 -

where Ci has rank ci' the number of i -cells of W. Since nected, H O(C.) = Z

C1 -

W

Co -

0

is simply con-

and H 1(C.) = 0, while H 2(C.) = H 2( W;Z) = 1I'2( W) is

a submodule of C 2 . Let S be the multiplicative system Z[A]-{O} in Z[G].

Zs

is nontrivial

=

an exact sequence 0 follows

that

Since A

0, and so on localizing the chain complex C. we obtain H 2 (C.)S -

is

H 2(C.)S

a

c O-c 1 +c2 = X(W), which must

C 2S -

stably

C 1S -

free

therefore be

COS -

0 from which it

Z[G]S-module

nonnegative. As

of

rank

H 2(C.) is a

submodule of C 2 , which embeds in C 2S ' it is 0 if and only if its localization is O. Thus W is contractible if and only if X(W) - O. 0

The assumption that to show that

W be 2-dimensional is not needed in order

W aspherical implies that X(W) = 0; this is in fact Rosset's

application of his lemma. Gottlieb obtained the first such result in the case of an aspherical complex whose fundamental group had nontrivial centre [Go 1965]. The

lemmas

of

Kaplansky

and Rosset

have

been

used

in

related

ways in connection with the Whitehead conjecture on the asphericity of subcomplexes of 2-dimensional K(G ,1)-complexes (cf. [Dy 1987] and the references therein). Corollary 1 If a

finitely presentable group G bas a nontrivial torsion

free abelian normal subgroup tben it bas deficiency at most 1. If G bas deficiency 1 and is not Z

tben it bas

finite geometric dimension 2. If

moreover tbe centre CG of G is nontrivial and G is nonabelian tben CG is infinite cyclic and tbe commutator subgroup G' is Proof Let P be a finite presentation for G

free.

and let C(P) be the related

2-complex. Then X(C(P» = 1-del P and so the theorem implies directly all but the last two assertions, which then follow from [B: Theorem 8.8].

As the groups of classical links are all deficiency

)

1,

this

results of Murasugi.

corollary

implies

immediately

0

torsion free and have the

above-mentioned

LocaIization and Asphericily Corollary

2

a

If

39

has deficiency 1 and is nonabelian and O/G'

Z,

then G' is infinite.

= a

Proof Let C be a finite 2-complex with 1T1 (C) were finite then

a

= o.

and X(C)

If A'

would have an infinite cyclic subgroup of finite index.

The corresponding covering space of C would be a finite 2-complex with fundamental group Z

and Euler characteristic

o.

It is easy to see that the

a

universal cover of such a complex must be contractible, and so

must be

torsion free, and therefore infinite cyclic. 0

This corollary does sufficient

to work

with

the

quick proof that if the group

not

really

commutative IT

need

Rosset's

ring I\.

Note

Lemma, that

for

this

it

is

gives a

of a nontrivial classical knot K

has fin-

itely generated commutator subgroup then it has one end. It then follows easily from Poincare duality that

is aspherical.

X(K)

A cyclic branched cover of S3, branched over a knot

connected sum of

the cyclic branched covers of

ITT: rK

prime

K, is the

of K. 2 These are irreducible, and cannot be S1xS [PI 1984]. Therefore the commutator subgroup of

the

factors

is a free product of finite groups and PDt-

groups, and is never a nontrivial free group. (Thus if

ITT: rK

and not Zit has cohomological dimension 4). Since

K

ITT: r

is torsion free

has a cen tral ele-

ment of infinite order, Corollary 1 implies that it cannot have deficiency 1, and so in particular

T: rK

cannot be a

nontrivial homotopy

ribbon 2-knot

(cf. [Co 1983]).

Some of the arguments of the next few chapters may be seen in microcosm

in

next theorem. We shall let ¢> denote the group with a 2>. The centralizer of a normal subgroup A of presentation 1 then TrL does

not have any such pair of subgroups T, group TrL

Proof The

MT

4 and 0 otherwise. Therefore OtT

M. The second assertion then follows from [B: Proposition 4.9].

Corollary

in

is

the

u.

fundamental group of

the closed 4-manifold

obtained by surgery on L, which has Euler characteristic 2-21-'. 0 Corollary

3

If

the

fundamental group of a closed 4-manifold N has an

abelian subgroup A of

finite index then X(N)

;it

0, and if X(N) -

0 then

A has rank I, 2 or 4.

Proof By passing to a subgroup of finite index we may assume that N

is

that Tr 1(N) A and is free abelian, of rank p say. We may clearly assume tha t p > 1. If P > 2 the theorem implies tha t either

orientable, and

X(N) > 0 or N is aspherical, and then p

=

4. If P = 2 then the localized

spectral sequence still collapses, and Poincare duality implies that the only nonzero localized homology module has rank X(N), which therefore must be nonnegative. 0

43

Localization and Asphericity

The manifolds Sl XS 3, SlXS 1 XS 2 and SlXS 1 XS 1 XS 1 have Euler characteristic

° and

fundamental group free

abelian of rank

1, 2

and 4

respectively. (See also Corollary 3 of Theorem 3 of Chapter 7). Corollary

finite (i.e.,

If

.. Tr

Tr

is a virtually abelian 2-knot group tben eitber

is virtually Z) or

is torsion

Tr

is

free and virtually Z4.

Proof It is readily verified tha t a group with abelianiza tion Z Z

Tr'

is virtually

'if and only if its commutator subgroup is finite, while no such group

can be virtually Z2 or Z3. 0

We shall determine completely such 2-knot groups in Chapters 4 and 6. The cohomological conditions In this section we shall show that the cohomological hypotheses of Theorem 3 are automatically satisfied if the group UIT is large enough. If I

is a finitely generated group then e(l)

the number of ends of I. If I

Lemma

1

is infinite H°(J;Z[I])

° also

one end then H1(J;Z [I]) =

0, 1, 2 or

(>=

finitely generated tben Hr(A;F) Proof Let B

=

be a free

>=

° if

i < r. If A is torsion

2.4. 1

a

has

Therefore

>=

°

~

r. If

is finitely generated and

Since B is an FP group and F is free

Hi(B;Z[Bl)(i/)Z[B1F

Hi (B;F) =·If

but A is not

of finite rank s

we may assume B has rank r and if A

B-module, Hi(B;F)

CD

free

0.

abelian subgroup of A

torsion free we may take B = A. as

if I

[Sp 19491.

and finitely generated tben Hr(A;F) ~ Z(1). If r
HP+q(A;F). 0

44

Localization and Asphericity

Theorem

Let I be a finitely generated group with IIJ' ;; Z and

4

which has an abelian normal subgroup A of rank at least 2. Then HS(J;ZII]) =

Proof

By

° for

Lemma

s ~ 2. E~q

the

1

terms

HP(JIA;Hq(A;ZII])) => HP+q(J;ZIJ»

of

vanish

the

LHS

spectral

for

q ~ 2, if A

sequence has

rank

greater than 2, or if it has rank 2 and is not finitely generated. If A

is

finitely generated and of rank 2 then we may assume that it is free, and E~q

=

° for

q ~ 1.

I

Moreover

Theorem 3), so E~2

must

H0(JIA ;ZIJIA])

clude that HS(J;ZII» =

° for

Corollary If a 2-knot group

=

be

infinite

° also.

(cf.

Corollary

4

of

In all cases we may con-

s ~ 2. 0

Tr

has a nontrivial torsion

free abelian

normal subgroup A then the rank of A is at most 4. Proof This is an immediate consequence of Theorems 3 and 4. 0

In Chapter 2 we saw that every finitely generated abelian group is the centre of some 3-knot group. The rank 1 case is somewhat more delicate. In the next theorem we shall let F(a ,tY' denote the set of all words in the second commutator subgroup of the

free

group on

(a

,0. As in Chapter 2, we

shall

Ie t

zA

denote the Z -torsion subgroup of an abelian group A.

Theorem

S

Let I be a finitely generated group with IIJ' ;; Z

and

which has an abelian normal subgroup A of rank 1. If e(JIA) = J' is

= 1 HS(J;ZII]) =

finite. If e(JIA)

entable then

and moreover A ;; Z

° for

or I is

° then

finitely pres-

s ~ 2. If e(JIA) = 2 then IlzA has

a finite normal subgroup N such that the quotient has a presentation . Since

we must have m-II = ±1. Now I

has a subgroup of finite index which maps onto Z

abelian kernel A. Therefore if I

with

is finitely presentable, this subgroup is a

constructible solvable group by (BB 19761 and (BS 19781, and so I ally torsion free. We may then assume

that zA = O. Moreover H

is virtuis then

also finitely presentable, and so it has an equivalent presentation of the form

for some sufficiently large

T.

By a Reidemeister-Schreier rewriting process

(MKS: page 1581 we get a presentation

for H. Clearly H

may be obtained from the group with presenta tion

Localization and Asphericity

46

as a direct limit of a sequence of amalgamated free products, and so contains

this

group

ZlmZ.ZI(m+l)Z

as

a

subgroup.

with

presentation

But

this group maps onto the group via the ·map

sending a 0 to c , a r+l to b and a I' . . . a r

to I, and so can only be

abelian if m or m + 1 is 1. In both cases we then have J I N

When J

=

H ::; 4>. 0

is finitely presentable, the last case of Theorem 5 may

also be extracted from [Tr 19741 or [HK 19781. Is the finite presentability of J needed in the case when e (J I A) = 11 Locally-finite subgronps A

group is said to be locally-finite

if every finitely generated

subgroup is finite. In any group the union of all the locally-finite normal subgroups is the unique maximal locally-finite normal subgroup [R: Chapter 12.11. (We use the hyphen to avoid confusion with the stricter notion of locally-Uinite and normal) subgroup). Clearly

there are no nontrivial maps

from such a group to a torsion free group such as Q. This notion is of particular interest in connection with solvable groups.

Since every finitely genera ted torsion solvable group is finite [R:

5.4.111, if 0

is a finitely genera ted infinite solvable group and T

maximal locally-finite normal subgroup then OIT is nontrivial. it

has

a

nontrivial

abelian

normal

subgroup, which

is

is its

Therefore

necessarily

torsion

free. Thus we may apply the theorems of the preceeding two sections to 4-manifolds with such groups. We shall consider solvable 2-knot groups in Chapter 6. For the present we shall give a more general result. Theorem

6

Let Tr be the group of a 2-knot K and T be its maximal

locally - finite normal subgroup, and suppose Tr has a normal subgroup U such tha t U IT is a nontrivial abelian group. If U IT has rank 1 assume also that e(TrIU)
, so the relations {rl' . .

rq,w} may

be assumed to be words in F(a ,t)". On adjoining finitely many more relations, we find tha t unless

D

1 there is a subquotient of G' (and hence

of Tr) which is free, contrary to Tr being locally-finite by metabelian. 0

We shall see in Chapter 4 that if Tr' is infinite then T is either trivial or infinite. We know of no examples in which T is infinite. PD-groups, asphericity and orientability If M

is an aspherical closed orient able 4-manifold then Tr 1(M) is

a PD: -group. Since we may increase the homology of M without changing the fundamental group by taking the connected sum with a l-connected 4manifold, the converse is in general false. However it is conceivable

that

48

Localization and Asphericity

every PD: -group 0 manifold, N

is the fundamental group of some such aspherical 4-

say. We then have X(N) = q(O). In this section we shall see

that in certain circumstances a 4-manifold whose group is a PD: -group must be aspherical. If f:M -

is an (n-l)-connected degree 1 map between closed

N

orient able 2n-manifolds with fundamental group 0, the only obstruction to

=

its being a homotopy equivalence is Hn (f)

kerU .:7r n(M) -

7r n (N».

Argu-

ing as in Theorem 3 we may show that Hn({) is a stably free module of rank (-l)n(X(M)-X(N», and so f is an integral homology equivalence.

Z[O]-

is a homotopy equivalence if it

We shall next adapt this argument to

a case in which it is not known a priori that the map has degree 1. Theorem 7 Let N be a closed orientable 4-manifold and 0

=

classifying map

and only if

o

f:N -

K(O,l) is a bomotopy equivalence

is a PD: -group and

if

7r

(N). Tbe 1

induces a rational bomology equivalence.

f

Proof As these conditions are clearly necessary, we need only show they are sufficient. Let C., D. complexes of Since

the

and E.

universal covers

HS(O;Z[G)) = 0

for

be

the

equivariant cellular chain

and (K(G,l),ii)

ii, K(O,l)

s < 4,

Poincare

that

duality

respectively.

together

with

the

universal coefficient spectral sequence give an isomorphism of H 2(C.) with

=

HomZ[O](H 2(C.),Z[G)) as in Theorem 3, while Hi(C.)

Since

Q~H2(C.)

trivial

maps

Z[G]

=

As

H 2(ii;Q).

homology

stably free

monomorphically

module

Q[G ]-module

is

K(O,l)

of

Q~E.

to

Q[O],

contractible, is

0 if s

H (C.) 2

the

Q~H3(E.)

by [W: Lemma 2.3]. Since

only

0 or 2.

embeds possible

H 2(N;Q)

f

,.&

which

in nonis

a

induces a rational

homology equivalence the Euler characteristics of Nand K(O,l) are equal. As

these

are

sequence 0 is

also C. -

O. Therefore

the

the

Euler characteristics of C.

D. -

stably

E. -

free

and

D.,

and

as

0 is exact, the Euler characteristic of E. Q[O]-module

H 2(N;Q)

=

Q~H3(E.)

rank 0 and so must in fact be 0, by Kaplansky's Lemma. Thus H 2(C.) and f

is a homotopy equivalence.

the

0

has

=

0

49

Localization and Aspbericity

Suppose

Corollary

tbat G is a PDt-group over Q and tbat tbe cobo-

mology ring H-(N;Q) is generated by Hl(N;Q). Tben N is aspberical. Proof

The

classifying

map

N

from

K(G,1)

to

is

clearly

a

rational

(co)homology equivalence and so the theorem applies. 0

Theorem

Let K be a 2-knot wbose group Tr is a PDt-group over a

8

field F sucb tbat Hl(Tr';F)

O. Tben

,.&

tbe classifying map f

to K(Tr,1) induces a bomology equivalence

from

M(K)

witb coefficients F.

Proof The infinite cyclic covers M

and K(Tr,lY "" K(Tr',l) each satisfy Mil-

nor

3

duality

f':M -

of

K(rr',1)

f'l:Hl(M;F)

formal

dimension

f

of

classifies

Hl(Tr';F)

tr'

with

coefficients

f' l:Hl(Tr';F)

and

F

and

Therefore

the

induced

Hl(M;F)

are

also

Trl(M).

the

lift maps

isomor-

phisms. Since Tr 2 K(IT',l) = 0 the map f' is 2-connected and so Whitehead's theorem ISp: page 3991 implies that f' 2:H2(M;F) - H 2(Tr';F) is an epimorTherefore the map f' 31M 1n:H1(Tr';F) -

phism.

=

since by the projection formula

f' 31M 1nc

H 1(1T';F)

assumption,

H 2(Tr';F)

ISp: 0

,.&

page and

2541. hence

By

f' 31M 1

,.&

O.

On

H 2(Tr';F) is an epimorphism, f' 2(IM 1nf' l(c»

Hl(Tr';F),.& 0, considering

between the Wang sequences of the projections of M onto

K(Tr,l)

we

see

that

f 41M1 '" 0 and so

f

so the

for all c

in

by

duality

map

induced

onto M and K(Tr',1)

induces

isomorphisms

in

(co)homology with coefficients F. 0

Corollary Let K be a 2-knot wbose group Tr is a PDt-group sucb tbat

Tr'

,.&

Proof

Tr".

Tben M(K) is aspberical.

Since

Tr' '" Tr"

there

is

a

field

F

such

that

H 1(Tr';F),.& O.

By

Theorem 8 the classifying map has nonzero degree and therefore induces a rational homology equivalence, so the corollary follows from Theorem 7. 0

As a contrast we have the following theorem.

50

Loca1ization and Asphericity

Theorem suppose

9

Let K

be a 2-knot wbose group Tr bas deficiency I, and

tbat Tr' '" Tr".

Tben Tr 2 (M(K»

'" 0, and Tr is not a PD: -group.

there is a field F such that H 1(M';F) ;:; H 1(Tr';F) is

Proof Since Tr' '" Tr"

nonzero. Milnor duality then implies that H 2 (M' ;F) ,.& O. On the other hand H 2 (Tr';F) = 0 since defTr = 1 (cf. [B: Section 8.51 or [H: page 42]), and so the Hurewicz map from Tr 2 (M) = Tr 2 (M')

to H 2 (M';F) is onto

[Ho 19421.

This proves the first assertion, and the second then follows from the Corollary immediately above. 0

For

2-knot

groups

the

assumption

of

orientability

is

usually

redundant. Theorem tbat

10

Let K

be a 2-knot wbose group Tr is a PD 4 -group sucb

H 1(Tr';Z!2Z) '" O. Tben

Proof

The

classifying

~map

w 1(Tr) = 0, i.e., Tr is of orientabJe f :M(K) -

K(Tr,n

is

a

type.

Z !2Z -cohomology

equivalence by Theorem 8, since every PD 4 -group is orientable over Z!2Z. The orientation character

wI of a 4-dimensional Poincare duality complex

is characterized by the Wu formula w lUx classes

X

=

(J2(x) for all Z!2Z -cohomology

of degree 3 [Sp: page 3501. Therefore wI (M) = f l(w 1 (Tr». Since

M is orientable and f 1 is injective we see that w l(Tr)

=

O. 0

We may use this theorem to give another example of a 3-:knot group which is not a 2-knot group. Let A be a 3X3 integral matrix with detA

-I,

det(A -I) = ±1

and

det(A(2)_1) = ±1.

(Here

A(2)

is

the

induced automorphism of H 2 (Z3;Z) = Z3AZ 3: in classical terms it is the second compound of A. When the first two conditions hold, the third is equivalent to det(A+1) = ±1. It may be shown that there are only 2 such such matrices, up to conjugacy and inversion. Cf. [New: page 52]).

Then A

determines an orientation reversing homeomorphism of SlXS1XS1. The fundamental group of the mapping torus of this homeomorphism is the HNN extension Z3 -A' which is a PD 4 -group of nonorientable type. It is easily

51

Loca1ization and Asphericity

seen to be a 3-knot group, but by Theorem 10 cannot be a 2-knot group. (Cappell and Shane son used such matrices and mapping tori to construct PL 4-manifolds

homotopy

equivalent

but

not

PL

homeomorphic

to

[CS

RP4

1976')). If

every

Tr

(torsion

PD 4 -group?

is

a

free)

PD 4 -group 2-knot

and

group

with

Tr

Is every 3-knot group

is

Tr' = Tr",

still

M

aspherical?

HS(Tr;Z[Tr)) = 0

for

s

~

2

Is

a

which is also a PD 4 -group a 2-knot

group? Finally we shall show that any 2-knot whose group is a PD 4group must be irreducible. Theorem 11 Let G be a PDn -group over 0

witb n > 2. Tben 0

is

not a nontrivial free product witb amalgamation over a cyclic subgroup. Proof If G

is a nontrivial free product 0

infinite index in O. Therefore if 0 A

9.22J.

Moreover

if

A.CB

then A

have

the subgroups

at most n-1, by [B: Proposi-

C is cyclic then b.dOC

~

1.

A

argument (as in [B: Theorem 2.10)) then shows tha t b.d.OO

Mayer-Vietoris ~

max{n -1, 2}.

0

Thus we must have n = 2. Corollary If

and B

is a PDn -group over 0

and B have homological dimension over 0

tion

=

K is a 2-knot sucb tbat M(K) is aspberical tben K is not

a nontrivial satellite knot.

In particular, K is irreducible.

Proof Let K 1 and K 2 be two 2-knots, and let "1 be an element of TrK 1· If "1 has finite order let q be that order; otherwise let q = O. Let

a

me ridian

in

Tr K 2.

Then

(TrK 2/«w q »).CTrK l' where

by

van

Kampen's

Theorem

the amalgamation is over C = Z/qZ

is identified with "1 in TrK 1 [Ka 1983J. 0

w be

TrL.(K 2;K 1,"1) =

and

w

52 Chaptcr 4

THE RANK 1 CASE It is a well known consequence of the asphericity of the comple-

ments of classical knots that classical knot groups are torsion free. This is also true of any 2-knot group which has a nontrivial torsion free abelian normal subgroup of rank at least 2, by Theorems 3 and 4 of Chapter 3. The first examples of higher dimensional knots whose groups have

torsion

were given by Mazur (Ma 1962] and Fox (Fo 1962]. Their examples have finite commutator subgroup, and hence in each of them some meridian is a central element of infinite order. In

power of a

this chapter we

shall

determine all the 2-knot groups with finite commutator subgroup, and we shall also consider the

larger class of groups having abelian normal sub-

groups of rank 1. Most of the groups

7f

with

7f'

finite can be realized by

twist

spinning.

study

Mazur's example. Fox used his method of hyperplane cross sections,

but his knots

This construction was introduced by were later shown to be also

Fox also gave

Zeeman

twist spun knots

in order

to

(Ka 1983'].

another striking example, with group , which is certainly

not even a fib red knot as ' is not finitely generated. If

is a 2-knot group with an abelian normal subgroup A

7f

rank

1

then either

over

a

(e(7fIA

group

is

7f'

= 1) or

(e(7fIA) =

2) or

7f

finite (e (7f1 A) = 0) or

7f/zA

is

a

PDt-group

is an extension of by a finite normal sub-

e(7fIA)

<X>.

After settling the case when

7f'

ite, we shall prove two general theorems. We first show that if A contained

In

7f'

and

if

Next we show that if A

of

moreover

e(7fIA)

1

then

is contained in Tr' and

7f'

Tr'

is

a

is, finis not

PDt-group.

is finitely presentable

then it is a PDt -group with nontrivial centre. Finally we shall show that if e (7f1 A)

2 then

7f

must be .

Cohomological periodicity We saw in Chapter 2 that if the commutator subgroup of a 2knot

group

7f

is

finite,

then all of its abelian subgroups are

cyclic, and

therefore Tr' has periodic cohomology (CE: page 262]. We shall establish this fact directly, in a stronger form, in our next

theorem. (We shall use

full strength of the theorem in Chapter 7). Theorcm 1 Let K be a 2-knot witb group

7f

sucb tbat

7f'

is

finite.

the

The RanIr: I Case

53

Tben M(K) is homotopy equivalent to S3. MC be

Proof Let C be an infinite cyclic central subgroup of 7f, and let the covering space of M with group C. Then 4-manifold

with

homology

fundamental

groups

of

M

r = Z(C] = Z(c,c- 1 ]. onto

MC'

may By

multiplication

group be

the

X(M ) = (7f:C]X(M) = O. The C regarded as modules over the ring Z, and

Wang

c-l

by

MC is a closed orientable

sequence

for

H 2(M;Z)

maps

the onto

projection of

M

itself.

by

But

equivariant Poincare duality and the Universal Coefficient spectral sequence

H 2(M;Z) = Hom r (H 2(M;Z),n. Hence H 2(M;Z) == O. Since 7f 1(M ) C two ends H 3(M;Z);;;; Z and since M is an open 4-manifold

we have has

H 4(M;Z) == O. Therefore the map from S3 to M representing a generator of 7f3(M) is a homotopy equivalence. 0

Tbe commuta tor subgroup 7f' bas cobomological period dividing 4,

Corollary

and tbe meridianal automorpbism induces tbe identity on H 3(7f';Z).

Proof The first assertion follows immediately from the Cartan-Leray spectral

sequence

for

the

projection p

of

M '"

S3

M

onto

357». By the Wang sequence for the projection of M

(CE:

(cf.

page

onto M we see that

the meridianal automorphism induces the identity on H 3(M ;Z). As the spectral

sequence

also

gives

H 3(7f';Z) ~ Coker(H 3(P» ~ Z/ I Tr'1 Z

the

second

assertion is also immediate. 0

We dimensional

may

knot

greater than 3

use

this

groups then

corollary

which

are

not

to

give

further

examples

of

2-knot

groups.

If p

a

is

high prime

ZXSL(2,p) is a 3-knot group with commutator sub-

group the finite superperfect group SL(2,p) (cf. the discussion of centres in Chapter 2). However as

SL(2,p) has cohomological period p-l (if p

iii

1

mod (4» or 2(P -1) (if p ... 3 mod (4» (LM 1978], it can only be the commutator subgroup of a 2-knot group if p

== 5.

The group

group of

knot;

this

the

5-twist

spin of

the

example found by Mazur (Ma 1962].

trefoil

was

zxr*

is

the

essentially

the

The Rank I Case

54

We shall follow· the exposition of Plotnick and Suciu IPS 1987] (rather

than

the

original

one

of

(Hi

1977]) in determining

which

finite

groups with cohomological period 4 have meridianal automorphisms. Let 0(1) be the quaternion group, which has a presentation <x ,y: x 2 = (xy)2 y2 >, be the automorphism which sends x

and y

to y

and xy respec-

and let

(1'

tively.

For each k ;;. 1 let T(k) be the group with presentation

(Thus T(k)' ~ 0(1), and T(k) is a semidirect product O(1)X(1'Zl3 k Z).

The

binary icosahedral group /" has a presentation <x ,y: x 2 = (xy)3 = y5>. Theorem

Let

2

7f

be a 2-knot group with

finite.

7f'

Then

7f'

~ PXZlnZ

where P ~ 1, 0(1), T(k) or /" and (n ,2: P:) = 1. Proof All the finite groups with the property that every abelian subgroup is cyclic are listed, in 6 classes, on pages 179 and 195 of (Wo]. As meridianal

automorphism

induces

meridianal

a

of

the

commutator

automorphism on

the

subgroup

quotient

of

by

a

knot

any

the

group

characteristic

subgroup, we may dismiss from consideration those which have abelianization cyclic of even order. There remain types 1,11,111 and V. Each

,

phism

=

on

the

a jb k

abelianization.

(1'(a r) then implies

(1'

Therefore

that irk _ ir

= 1

-

presenta tion

with

and

rn

1

must induce a meridianal automor-

(k,n) = (k-1,n) = 1.

where

(m,n(r-1)

where

mod (m). A meridional automorphism

(1'(b)

metacyclic,

(1'(a) = a i The

where

condition

mod (m), and so r

=

(i ,m) = 1 that

and

(1'(bab- 1 ) =

1. Therefore

the

group is cyclic of odd order. Each group of type II has a subgroup of type I of index 2, and has a presentation

where

p2

iii

rq - 1

!IS

1 mod (m),

q+1 ... 0 mod 2 u and q2 _ 1 mod

n = 2u v (n).

for

some

u ;;. 2

and

odd v,

55

The Rank I Case

The condi tions (m ,n (r -1» = 1 and r n _ m

1 mod (m) imply

is odd and (m ,n) = 1. The subgroup generated by {a ,b

2u

tha t

} is the unique

maximal subgroup of odd order, and so is characteristic. Therefore a meridianal automorphism on such a group induces a

meridianal

automorphism on

the quotient, which has a presentation

2

only

u

=

I, c

elements

2

of

=

u b 2 -1 ,cbc- 1

order

2u

in

=

this

bq>.

quotient

are

the

odd

powers of b, and so no automorphism can be meridiana!' Therefore we may assume that u = 2. The subgroup generated by a

is also characteristic. Any meridia-

nal automorphism of the quotient by this subgroup must map b to bee for and so must map b 4 to b 2e (q+1). Therefore (q+l,v) = 1 and the

SOme e

then imply that q

congruences above

!!!!

1 mod

Hence the quotient is

(v).

isomorphic to O(1)XZ/vZ. Thus a meridianal automorphism of a group of type II with such a presentation must map a, b 4 , b V and c to a f , a8b4e, ahbvc and aib v respectively.

b 4 ab -4

=

{prY ..

be

Since

ar

frY,

and 4e fr ..

it

must preserve the 1 cac- = a P , we obtain

fr 4

and

frY

!!!!fp

the

group is

the

further

congruences

mod (m). As moreover

1 and p2 .. 1 mod (m) and (4(e -l),v)

mod (m). Therefore

relations

I, we

=

isomorphic

to

find

that

(f

r

,m) must

... p

iii

1

O(1)XZ/m vZ, and mv is

odd. Each group of type III is an extension of a group of type I by

0(1), and has a presentation

where

the

subgroup

order

n

of

b

is

an odd

0(1) is characteristic, the

multiple

quotient

of

admits

3. Since a

the

Sylow

2-

meridianal automor-

phism; since it is of type I it must be cyclic, and so r = 1. Let n

=

3k s

where s is not divisible by 3. Then the subgroup generated by ab 3 is cenIral and of order MS. The subgroup generated by {x,y,b s } is isomorphic to

56

The Rank 1 Case

T(k),

and

(ms,6)

so

the

whole

group

is

isomorphic

to

T(k)XZ/msZ,

where

1.

The

only groups of

type

V

that

we

need consider are

direct

products IXSL(2,p) where I is of type I, p is a prime greater than 3 and

(I I 1,1 SL(2,p) I) = 1.

If

such

a

direct

product

(with

factors

of

coprime

order) admits a meridianal automorphism, then so do its factors. Therefore I

is cyclic of odd order.

As remarked above, the cohomological dimension

of SL(2,p) is greater than 4 if p > 5. This completes the theorem. D

It is well known that each such group is the fundamental group of a 3-dimensional spherical space form IWo]. In particular it has

trivial

second homology. Therefore each meridianal automorphism of such a group can be

realized by some

3-knot group. Plotnick and Suciu study n -knots

which are fibred with fibre a punctured spherical space form, and show that if n > 2 then "' must be cyclic IPS 1987]. Meridianal automorphisms Having found the groups with cohomological period 4 which admit

some

meridianal

phisms (up

to

We shall show

automorphism, we must inversion

next determine

and conjugacy in

that in fact

the

outer

all such automor-

automorphism group).

there is in each case just one 2-knot group

with a given finite commutator subgroup. Throughout this section " shall be a 2-knot group with finite commutator subgroup. Our results shall be developed in a number of lemmas and then summarized in a theorem. The first lemma is self-evident. Lemma 1 If a group G

HXI witb (IHI,III) = 1 tben an automorph-

ism '" of G corresponds to a pair of automorpbisms "'H and "'I of H and I respectively, and'" is meridianal if and only if "'H and "'I are.

D Lemma 2

Tbe meridianal automorpbism of a cyclic direct

factor of rr' is

tbe involution.

Proof The

endomorphism

Is ]:x_x s

of

the

cyclic group of order m

is

a

The Rank I Case

S7

meridianal automorphism if and only if (s -I,m) is

a

direct

factor

of

",

then

it

is

a

=

=

(s,m)

direct

1. If the

summand

of

group

"'I""

=

HI (M(K);A) and so Theorem 3 of Chapter 2 implies that s 2 "" 1 mod (m). Hence we must have s

Lemma

3

iii

-1 mod (m). 0

An automorphism of 0(1) is meridianal if and only if its

image in Out(O(1»

equals that of

17

or

17-

1.

Proof It is easy to see that an automorphism of 0(1) induces the identity on 0(1)10 (1)' if and only if it is inner, and that every automorphism of

0(1)10(1)'

lifts

to

one

0(1).

of

Therefore

Out(O(1»

=

Aut(O(1)IO(1)').

Moreover as 0(1) is solvable an automorphism is meridianal if and only if the

induced

automorphism

0(1)10 (1)'

of

represented by the images of

17

is

meridianal.

The

latter

are

and 17- 1 in Out(O(1». 0

A more detailed calculation shows that every meridianal automorphism of 0(1) is conjugate to

Lemma

4

17

or

17-

1 by an inner automorphism.

All nontrivial automorphisms of I" are meridianal. Moreover

each automorphism is conjugate

to its inverse, and Out(J") = Z/2Z.

Proof An elementary calculation shows that if an automorphism of a group

o

induces the identity on OleO, then it is the identity on all commuta-

tors. Therefore if 0

is a perfect group the natural map from Aut(O) to

Aut. Then every subgroup of finite index in (1) = is

Cm)

to

some

m

each

f

from G = "ICY) to (m) for some

finite

kernel. Then the integral homology groups of the infinite cyclic covering space Y determined by G = f- 1 C<SCm» are finitely generated A-torsion modules, and H 2 Ca;Z) is Proof

Since

Y

is

compact

and

finite cyclic of odd order.

A

is

noe therian,

the

groups

HiC}>;Z) = HiCY;A) are finitely generated as A-modules. Since Y is orien table, XCY) = 0 and H 1CY;Z) has rank I, H CY;Z) is finite and the rest of 2 the first assertion follows from the Wang sequence for the projection of }> onto Y. By Poincare duality and Hopf's theorem H 2 Ca;Z) is a quotient of Ext ~ Ca/(:}',A).

CCf. Theorem 3 of Chapter 2). By assumption there is an

exact sequence 0 -

T -

ala' -<Scm) ~ N(t _2m) -

0 where T is a fin-

Therefore Ext ~ CGIG',A) ~ N(t -2m) and so H 2 CG;Z) is a quotient of A/C2 m t-l), which is isomorphic to Z[K) as an abelian group. ite A-module.

Now

GlkerCi) ~ Z[K)

also, and

H 2(Z[K);Z) = Z[K]AZ[K]

334)) = 0, and so by the LHS spectral sequence for

a as

Cby

[R: page

an extension of

Z[K] by kera) we see that H 2 Ca;Z) is finite. But a finite quotient of Z [K) is cyclic of odd order. 0 Lemma pi.

11

Let A

be an abelian group and F a

2, considered as a

product

field of characteristic

trivial A-module. Then the map induced by cup from H 1CA;F)AH 1CA;F) to H 2CA;F) is injective.

65

The Rank 1 Case

Proof We may identify H1 CA ;F) with HomCA,F) and H 2 CA;F) with {w:A 2 _FlaZw = 0}/{a1 [1[:A_F} where a1 [Ca ,b) = [Ca)+ [Cb)- [Cab) and aZwCa,b,c) = wCb,c)-wCab,c)+wCa,bc)-wCa,b) for all a, b, c

in A

maps [

in H 1CA;F) is

and w. The cup product of two elements [

and g

and set

represented by the function sending Ca,b) in A2 to [Ca)gCb) in F. There

is

a

natural monomorphism J.I

from

H 1CA;F)AH 1CA;F)

to

,,2CA ,F) Cthe space of skew symmetric bilinear maps from A2 to F ) given

J.lq:. [iAgiXa,b) = 'L({iCa)giCb)-[iCb)giCa».

by

H 1CA;F) are such that 'L[iUgi

from A

=

to F such that 'L[iCa)giCb)

that

=

[i' gi

in

hCa)+hCb)-hCab) for all a, b in A.

= 0 for all a,

b

in

abelian. Since J.I is a monomorphism, 'L[il\gi must be

o.

0

Then J.lq:.[iAgiXa,b)

=

Suppose

0 in H 2 CA;F). Then there is a function h

hCba)-hCab)

For more general groups G of characteristic 2 or the ring Z

A

since

A

is

and for coefficients including fields

the kernel of cup product may be related

to the subquotients of descending central series for G [Hi 19871. Lemma finite

12

Let rr be a 2-knot group which is an extension o[ by a

normal subgroup N.

Proof Let K Le t A

be

since N

Then N -;;; O(1) or is trivial.

be a 2-knot with such a group rr, and fix a meridian t in rr.

a maximal abelian

subgroup of N

and Ie t G 1 = C rrCA). Then

is finite and normal in rr the index m = [rr:G 11 is fini teo In par-

ticular t m is in G

and G 1 maps onto Z, with kernel 8 1 say. Let G be Then G has fini te index in the subgroup of rr generated by COl and t m 1

rr and so there is an epimorphism Moreover by

the

page

8

1061.

from G

onto Cm), with kernel A.

[ -lC$cm» is abelian, and is an extension of SCm) -;;; Z[*1

=

finite

[

abelian group A, and so is isomorphic to

Now

H 2 C8;z) is cyclic of

odd order, by

other hand, by [R: page 3341 it is isomorphic to fore A

A~Z[*1,

Lemma

by

[R:

10. On

the

AM~CA and let H the

right E-module

given

above

we

with

may

be

the conjugate action. From the three resolutions that e 1 F2 = e1He = e 1 Hf = O. (In fact

compute

eO F 2 = e 1 F 2 = 0, which is equivalent to the fact that the group has one

end).

Then

Poincare

duality

and

the

Universal

Coefficient

spectral

sequence give H 3 = 0 in either case, and an exact sequence

Now

since

the

skew

field

of

fractions

L

is

flat

H p CL(i5J=.C.) = L(i5J=.Hp' and so is nonzero only if p

as

a

right

module,

= 2. But since M has

Euler characteris tic 0, which is also the Euler characteristic of L(i5J=.C,. and therefore

of L(i5J=.H., we

e OH 2 = 0 Csince

e OH 2

may conclude

the e 2H f note

0 also. Therefore

contained in HomCL(i5J=.H 2 ,L» and e 1 H2 - 0 in which e 2 H 1 - HI

term has order 4 Cas an abelian group). But this is absurd as

right

=.-modules

= Ell f

that

L(i5J=.H 2 -

HomCH 2 ;E.) is

we have a short exact sequence 0 the middle

that

for

e2He

=.lIe = =./Ct 2 +tCa-1)+(a-1)3,a 4 -1)=.

= =.ICa 4+a 2+ 1,t +a 3+a 2+a )=.

instance

e 2Hf

contains

are

E/EnI f

each =

infinite. CTo E/Ca 4+a 2+1)

and

see as

a

this sub

The Rank 1 Case

69

E.-module). Thus there can be no such 2-knot. Therefore by Lemma 12 we must have rr = . 0

Corollary If the quotient of a 2-knot group rr by its maximal locally-finite

0

normal subgroup T is then T is either trivial or infinite.

In fact we believe that in this case T must be trivial, but have not ye t been able to prove this. The modules He and H f 0(0 presented by

1

group [Mi

of

19751.

cyclic fundamental groups.

The

M(p,q ,r)

The

is

triples

finite (2,q,2)

remaining 6 such

lead to 3 distinct manifolds, with groups 0(1), T easily

from

these

observations

and

Dunbar's

give

if

and lens

only

triples (with (p,q) = =

work

T(1) or 1-. It

that

no

if

spaces, with

2-knot

1)

follows whose

IV

The Rank 2 Case

group has commutator subgroup O(1)XZ/IlZ for some

11

> 1 cln hI

Iwhl

I

spin. (Note that the meridional automorphism of such a commutllnr IUItIIlIllI' has order 6). The fundamental group of M(2,3,6) is nilpotent; III Ih. ,lIh,'I aspherical Brieskorn 3-manifolds are finitely covered by circle bundl ..

\lVI'r

surfaces of hyperbolic type, and so their fundamental groups do nlll

l'dvlI

abelian normal subgroups of rank greater than 1. If p-1+ q -1+ r -1 ~ 1 then

the Seifert

fibration

r

and

= cp'q'

where (a,cq')

= (b,cP') = (p,q) =

exceptional fibres of mUltiplicity p', a and

1 exceptional

fibre

of

M(p,q,r) i~

Let p = ap', q -

essentially unique. (Cf. Theorem 3.8 of [Sc 1983']).

M(p,q,r)

hoa

b

exceptional fibres of mUltiplicity

(i'

of mUltiplicity

c, and

1.

so

Then

II.,'

the

triple {p, q, r}

is

determined by the Seifert structure of M(p,q ,r).

Theorem 7

Let M be

tbe r-fold cyclic brallcbed cover of S3, brallcbed

over a 1-knot K, and suppose tbat r > 2 alld tbat "1(M) bas a subgroup of but is Ilot

fillite illdex witb Ilolltrivial celltre alld illfillite abeliallizatioll virtually abeliall. Tbell K is a

torus kllOt, alld is determilled

ulliquely by M alld r. Proof The assumptions imply that "1(M) has one end, and so M is aspherical. If it were a connected sum then one of the summands would have to be

a

homotopy

branched over a

sphere, knot

and

would

be

summand of K.

a But

cyclic any

branched

cover

such homotopy

S3,

of

3-sphere

must be standard, by the proof of the Smith conjecture. Therefore

M

is

irreducible, and almost sufficiently large, and so must be Seifert fibred [Sc 19831. Now since M is not a flat 3-manifold we may assume that there is a Seifert fibration which is preserved by the automorphisms of the branched cover [MS 19861. Since r > 2 the fixed circle (the branch set in

M)

must

be a fibre of the fibration, which therefore passes to a Seifert fibration of X(K).

Thus K must be a torus knot [BZ 19671, and so M is a Brieskorn

manifold. The uniqueness follows as in the above paragraph. 0

If "I(M) is virtually abelian and infinite then a similar argument shows that M is irreducible, hence flat, and that only r

3 or 4 is possi-

ble. It is not hard to show that only one of the six closed orientable flat

80

The Rank 2 Case

3-manifolds is a cyclic branched cover of S3, branched over a knot, and the order of the cover must be 3. (See Theorems 6 and 8 of Chapter 6). Theorems 2 and 7 together with this observation imply that a classical knot k such that

7ft: rk

has centre of rank 2 and whose commutator subgroup has

a subgroup of finite index which maps onto Z

(for some r ;;. 3) must be a

torus knot. It is in fact clear from the tables of [Du 19831 that if the r-

fold cyclic branched cover of a classical r

;;. 3 then either the

and r

=

knot

is Seifert

fibred

for some

knot is a torus knot or it is the figure eight knot

3. All the knots whose 2-fold branched covers are Seifert fibred

are torus knots or Montesinos knots. (This class was fi,rst described in [Mo 19731, and includes the 2-bridge knots and pretzel knots). The number of distinct manifold there

knots can

whose be

2-fold branched cover is

arbitrarily

large

[Be

19841.

are distinct simple 1-knots whose

a

given Seifert

Moreover

for

fibred

each

r

3;;. 2

r-fold cyclic branched covers are

homeomorphic [Sa 1981, Ko 19861. Pao has observed that if K of finite order r

is a fibred 2-knot with monodromy

and if (r ,s) = 1 then the s -fold cyclic branched cover of

S4, branched over K, is again a 4-sphere and so the branch set gives

new 2-knot, which we shall call

the

a

s -fold cyclic branched cover of K.

This new knot is again fibred, with the same fibre and monodromy the s tb power of that of K

[Pa 1978, PI 19831. Using properties of S1-actions on

smooth homotopy 4-spheres, Plotnick obtains the following result. neorem

[PI

19861

Modulo

tbe 3-dimellsiollal Poillcare cOlljecture, tbe

class of all fibred 2-kllots witb periodic mOllodromy is precisely tbe class of all s - fold cyclic brallcbed covers of r-twist SpillS, wbere 0 < s < r alld (r,s) = 1. 0

Here ·periodic monodromy· means that the fibration of the exterior of the knot has a characteristic map which is of finite order. It is not in general sufficient that

the closed monodromy be represented by a map

of finite order. We shall call such knots brallcbed twist SpillS, for short. If we homotopy

restate

3-spheres

we

this

result

in

may

avoid

explicit

terms

of

twist

dependence

spinning knots on

the

in

Poincare

The Rank 2 Case

conjecture. directly

81

In our application in the next

that

theorem we are able

the homotopy 3-sphere arising

to show

there may be assumed to be

standard.

Theorem 8 A group

a

wbicb is Ilot

virtually solvable is tbe group of a

2-kllot wbicb is a cyclic brallcbed cover of a

twist SpUIl torus kllot if

alld ollly if it is a 3-kllot group, a PDt-group witb celltre of rallk 2, some Ilollzero power of a

subgroup of Proof If K

a'

weigbt elemellt beillg celltral, alld

bas a

fillite illdex witb illfillite abeliallizatioll. is a cyclic branched cover of the r-twist spin of the (p,q)-

torus knot then M(K) fibres over the circle with fibre M(p,q ,r) and monodromy of order r, and so the r tb over the

power of a meridian is central. More-

monodromy commutes with the

natural circle

action on

(cf. Lemma 1.1 of [Mi 1975]) and hence preserves a Seifert follows is

that

therefore

rr 1(M(p,q ,r»

M(p,q ,r)

fibration. It

the meridian commutes with the centre of rr 1(M(p,q ,r», which also is a PD

central

in

t -group

a.

Since

(with

the

above

exceptions)

with infinite cyclic cent re and which is virtu-

ally representable onto Z, the necessity of the conditions is evident.

a

Conversely, if

is

such a

group

group of a Seifert fibred 3-manifold, N over N

a'

is

the

fundamental

say, by Theorems 2 and 6. More-

at

is "sufficiently complicated" in the sense of [Zi 19791, since

not virtually solvable. Let t

be an element of

the whole group, and such tha t til we may

then

assume minimal).

Then

a

whose normal closure is

is central for some positive

G

is

11

(which

a/ is a semidirect product of

=

Z/IlZ with the normal subgroup G'. By Corollary 3.3 of [Zi 19791 there is a fibre preserving selfhomeomorphism phism of lifts

a'

determined by

1"

of N

inducing the outer automor-

t, which moreover can be so chosen that its

to the universal covering space

N

together with

generate a group of homeomorphisms isomorphic to

N

corresponding to

the

image of

t

in

a

fixed point set by Smith theory. (Note that point set of the map

1"

O.

the covering group The automorphism of

has a connected

N

1-dimensional

= R 3). Therefore

the fixed

in N is nonempty. Let P be a fixed point. Then P

determines a crosssection "'I = pxS 1 of the mapping perform surgery on "'I to obtain

a 2-knot

torus of

with group

a

t".

which

We is

may

fibred

82

The Rank 2 Case

with monodromy (of the fibration for the exterior

X)

of finite order.

We

may then apply the above theorem of Plotnick to conclude that the 2-knot is a branched twist spin of a knot in a homotopy 3-sphere. monodromy

respects

the

Seifert

fibration

and

leaves

the

Since the

centre

of

G'

invariant, the branch set must be a fibre, and the orbit manifold a Seifert fibred homotopy 3-sphere. Therefore the orbit knot is a fibre of a Seifert fibration of S3 and so is a torus knot. Thus

the 2-knot is a branched

twist spin of a torus knot. 0

It shall follow from the work of Chapter 6 that if rr is a virtu-

ally solvable 2-knot group in which some power of a weight element is central then either rr' is finite or rr is the group of the 2-twist spin of a Montesinos knot K(O I b;(3,l),(3,l),(3,±1»

(with b even) or of the 3-twist spin

of the figure eight knot or of the 6-twist spin of the trefoil knot. We might hope to avoid the appeal to Sl-actions implicit in our use of Plotnick's theorem by a homological argument to show that

t'

has

connected fixed point set. The projection onto the orbit space would then be a cyclic branched covering, branched over a knot, and we might then be able to show that the orbit space is simply connected, by using the fact that the normal closure of t fibred and

t'

in G is the whole group. Since N

is Seifert

is fibre preserving, the branch locus would then be a torus

knot in the standard 3-sphere.

However we have been unable thus far to

establish this connectedness directly. If p, q and r are relatively prime then M(p,q ,r) is an homology

sphere and the group rr of the r-twist spin of the (p,q)-torus knot has a central

element

rr -;:;; rr'XZ, and rr'

which

maps

to

a

generator

has weight 1. Moreover if t

of

rr/rr'.

It

follows

that

is a generator for the Z

summand, then an element b of rr' is a weight element for rr' if and only if bt is a weight element for rr.

This correspondance also gives a bijec-

tion between conjugacy classes of such weight elements. If we exclude the case (2,3,5) then rr' has infinitely many distinct weight orbits, and moreover there are weight elements such that no power is central [PI 1983]. Therefore we may obtain many 2-knots whose groups are as in Theorem 8 but which are not themselves branched twist spins, by surgery on such weight classes in M(p,q,r)XS l . Is there a 2-knot group which contains a rank 2 free

abelian

normal

subgroup

and

for

which

no

nonzero

power

of

any

The Rank 2 Case

H,'

weight element is central? If K

is a 2-knot with group as

aspherical, and so the

theorem implies

in Theorem 8

that it

then M(K) IA

is homotopy equivalenl

In

M(K 1) for some K 1 which is a branched twist spin of a torus knol. II h a well known open question as to whether homotopy equivalent aapherlcill closed manifolds

must be

homeomorphic. In

M(K) and M(K 1) must be that

if

K

is

homeomorphic.

fib red,

Chapter

8 we

topologically s -cobordant. Here

with

irreducible

fibre,

then

M(K)

shall lee

Ihal

we shall Ihnw and

M(K 1) are

This is a version of Proposition 6.1 of [PI 19861, startinK

from more algebraic hypotheses. Theorem

Let K be a

9

fibred 2-knot wbose group rr bas centre of

rank 2, some power of a weigbt element being central, and sucb tbat rr' bas a subgroup of tbe

finite index witb infinite a beJianization. Suppose tbat

fibre is irreducible. Tben M(K) is bomeomorpbic to M(K 1) wbere K 1

is some brancbed twist spin of a torus knot. Proof Let F F

be the closed fibre and :F-F the characteristic map.

Then

is a Seifert fibred manifold, as above. Now the automorphism of F con-

structed as in Theorem 8 induces the same outer automorphism of rr l(F) as , and so

these maps must be homotopic. Therefore they are in fact isoto-

pic, by [Sc 1985, BO 19861. The theorem now follows.

The

closed

fibre

of

any

fib red

2-knot

0

with

such

a

group

is

aspherical, and so is a connected sum F#P where F is irreducible and P is a homotopy 3-sphere. If we could show that the characteristic map may be isotoped

so

that

the

fake

3-cell (if

there

is one) is carried onto itself

then we would have K = K 1 #K 2 where K 1 is fibred with irreducible fibre and K 2 has group Z. We could then use Freedman's Unknotting Theorem to sidestep the assumption that the fibre be irreducible. Other twist spins We

may

also apply

Plotnick's

theorem in

attempting

to

under-

stand twist spins of other knots. As the arguments are similar to those of Theorems

8

nnd

9,

except

in

that

the

existence

of

homeomorphisms

of

84 finite

The Rank 2 Case order

and "homotopy

implies

isotopy"

require

different

justification,

while the conclusions are less satifactory, we shall not give proofs for the following assertions. (Cf. also Theorem 9 of Chapter 2). Let G be a 3-knot group which is a PDt-group in which some nonzero power of a weight element is central. If G'

is

the

fundamental

group of a hyperbolic 3-manifold and the 3-dimensional Poincare conjectnre is true then we may use the Rigidity Theorem of Mostow [Mo 1968] to show that G is the group of some branched twist spin K

of a simple non-

torus knot. Moreover if K 1 is any other fibred 2-knot with group G and hyperbolic fibre

then

M(K 1)

is homeomorphic

to

M(K).

In particular

the

simple knot and the order of the twist are uniquely determined. Similarly if G' is the fundamental group of a Haken, non-Seifert fibred

3-manifold and

we may use

the

[Zi 1982]

3-dimensional

to show

Poincare conjecture

that G

is

the

is

true

then

group of some branched

twist spin of a prime non torus knot. If moreover all finite group actions on the fibre are geometric then by [Zi 1986] the prime knot and the order of the twist are unique. However we do not yet have algebraic characterizations

of

the

groups

of

hyperbolic

or

Haken

3-manifolds

comparable

to

Theorem 6. (Question 18 of [Th 1982] asks whether every closed hyperbolic 3-manifold is finitely covered by a surface bundle over the circle). We raise the following questions. Is a 3-knot group which is a PD: -group in which some nonzero power of a weight element is central

the group of a branched twist spin of a prime knot? If K

is a 2-knot

such that rr' has one end and some power of a weight element is central in rr then is M(K) homeomorphic to a cyclic branched cover of M(T: rk) for some prime classical knot k and r ;;. 2, and if so are k and r unique?

85 Chapter 6

ASCENDING SERIES AND THE LARGE RANK CASES All but two of the 2-knot groups with abelian normal subgroups

of rank greater than 2 have commutator subgroup Z3 (as in the examples of Cappell and Shaneson)j the exceptions are virtually abelian of rank 4. We shall prove this after considering the more general class of groups with ascending series whose factors are either locally-finite or locally-nilpotent. If rr

is

such a 2-knot group and

T

subgroup then rrlT is in fact either Z length 4.

In the

latter case

is its maximal locally-finite normal or

. Then rq is a torsion free 2-stage

q = Z

(generated by

Z2 (generated by the images of x

the

and y).

image of z) and

Every finitely gen-

erated torsion free nilpotent group of Hirsch length 3 is isomorphic to Z3 or to r q for some q.

Lemma

1

Let D be a

torsion subgroup of GL(2,Q). Then D is

finite,

of order a t most 12.

Proof Let E

be a

finite

subgroup of D. If L

ue(L) is a lattice invariant under E, so E

is

a lattice

in

Q2

then

is conjugate to a (finite) sub-

group of GL(2,Z) and hence has order at most 12 (cf. [Z: page 85)). D

is locally finite

[K: page

subgroups and so also has order at most 12. 0

Theorem 2

As

105], it is an increasing union of its finite

Let J be a PDt-group over Q with J I/,

Z

which has

Ascending Series and the Large Rank Case

88

an ascending series witb factors eitber locally - finite or locally -nilpotent, and suppose tbat J bas no nontrivial locally - finite normal subgroup. Tben I' is a

finite extension of Z3 or of r q (for some natural number q).

Proof Let B be the Hirsch-Plotkin radical of 1', and let b be the Hirsch length of B. As in Theorem 1, B

~

b.d'OB

hence

~

~

b.d.OI'

abelian, of

torsion free

and b

is at least 2.

< b.d'OJ = 4 by [B: Theorem 9.22], and so

Since [J:I'] is infinite, b.d.OI'

b

is

3. Suppose that b = 2. Then B is locally-abelian,

rank 2. Let E

be

the

preimage in J

of the

maximal

locally-finite normal subgroup of JIB and let a:E-Aut(B) be the homomorphism

induced

by

conjugation.

Then

B

is

central

in

ker(er),

and

Schur's

Theorem then implies that B = ker(er) (as in Theorem 1). Moreover im(a) is a locally finite subgroup of Aut(B), which is in turn isomorphic to a subgroup of GL(2,O).

Therefore by Lemma 1 im(er) is finite and so EIB is a ~

b.d'OB + 1

(assuming I'IB is locally-finite) ~ 3 which is absurd, as J is a

PDt -group

finite

solvable

group.

I'

Now

~

E, for

over O. Let F be the preimage in I' group of I'IE. Then solvable and b.d'OF

FIE ~

is nontrivial

b.d.OI'

~

otherwise

b.d'OJ

of the maximal abelian normal subMoreover

F

is

the Hirsch length of F

is

at

and

3 and so

torsion

free.

most 3. Since it is at least b+l, it must equal 3 and so e-qual b.d'OF. Moreover I'IF must be a torsion group. This has two contradictory consequences. On the one hand FIE has rank 1 and so is central in I'IE. Using Schur's Theorem and the maximality of EIB we find that F

=

1'. On the

other hand [J:F] = co so c.d'OF ~ 3 by [St 1977]. Since F is solvable of Hirsch length 3 and virtually torsion free, this implies that F must be finitely generated [OS 1981]. But then I'II"E impossible

for

a

=

FIP ~ Z(J)z(FIP), which is

group (JIE) with infinite cyclic abelianization. Theretore

b = 3.

Since c.d'OB

0;;;

3 by [St 1977], b = c.d'OB and so B is finitely

generated [B: Theorem 7.14], and therefore must be isomorphic to Z3 or to

r q for some O. Finally let j be an element of J which is not in 1'. Then the subgroup generated by Bu{j} is a poly-Z group of Hirsch length 4 and so has finite

index in J

by [B: Theorem 9.221. Therefore J

group and B has finite index in 1'. 0

is a poly-Z

89

Ascending Series and the Large Rank Case

If we knew a priori that J was virtually poly-Z, we could sim-

plify the proof of this theorem by observing that every sub- and quotient group is then also virtually poly-Z. Abelian HP radical

In this section we shall show that if the Hirsch-Plotkin radical

H

of

the

commutator

subgroup J' = rrlT

of

the

quotient

of

a

2-knot

group rr by its maximal locally-finite normal subgroup T is Z3 then J'IH is

isomorphic

to

J'IH must be

a

finite

subgroup of SL(2,Z).

trivial, the four-group

V

We

shall

then show

that

or the tetrahedral group A 4 . In

particular rrlT is solvable (of derived length at most 4). If moreover rrlT is torsion free then rr' ;;;; Z3, with just two exceptions. As we have found no convenient reference listing the finite subgroups of SL(3,Z) we shall derive what we need in our next lemma. Since any

integral

matrix

of

finite

order

is

diagonalizable

over

the

complex

numbers the corresponding cyclotomic polynomial must divide the characteristic polynomial of the matrix. Thus in particular the finite cyclic subgroups of SL(2,Z) or SL(3,Z) have order I, 2, 3, 4 or 6. In fact the only other finite subgroups of GL(2,Z) are the dihedral groups of order 2, 4, 6, 8 or 12 [Z: page 851. (Note that -I is the only element of order 2 and determinant I, but that there are two conjugacy classes of elements of order 2 and determinant -1).

Let E be a

Lemma 2

finite subgroup of SL(3,Z). Then the order of E

divides 24, and E is either cyclic, dihedral, a semidirect product of ZI8Z or D8 with normal subgroup Z/3Z, or is A4 or S 4.

Proof If p

is an odd prime, A

with (p,q) = 1 then (/+pr A l

eo

is a 3X3 integral matrix and k = P v q modulo .

PEj, jE

If p is a meridianal automorphism of

°6 ,

then it must induce a

meridianal automorphism of 061A6' and so we must have

p

_

modulo E. Conversely any such automorphism is meridianal, for that 06 modulo «g-Ip(g)1 g ill 06>1>0

j

or j-l

it implies

is a perfect group, and therefore 6

99

Ascending Series and the Large Rank Case

is trivial as 0 6 is solvable. There are 32 elements in the cosets jEuj-1ii of Out(06). The centralizer of j in Out(06) is generated by ap and j, and has order 12. The distinct cose ts of this centralizer in Out(O 6) are represented by

n,

a, "I, a "I,

i, ia, i"l, ia"l}. Conjugating j

and j-1 by these

elements we get 16 distinct elements of jEuj-1ii, which all give rise to the group with presentation 1, txt- 1 = xy, tyt- 1 = x>.

However this group cannot be a PDt-group, as already the subgroup generated by {x 2 , y2, z2,

t}

is nonorientable. The

elements ja and

jp

also

have centralizers of order 12 and their conjugates exhaust the remaining 16 elements of jEuj-1ii. Each of ja and jp is conjugate to its inverse (via i), and so

the groups 0(+) and 0(-) that they give rise

to are distinct.

Moreover these antomorphisms are orientation preserving on A6 and hence on 0 6 (in fact

ja =

(ja)4)

and so 0(+) and 0(-) are PDt-groups.

In each case A6 is an abelian normal subgroup of rank 3, while the subgroup generated by A6U{t6} is an abelian normal subgroup of rank 4. Since the characteristic polynomial of t

acting on A6 is X 3 -1, the only

candidates for normal subgroups of rank less than 3 contained in A6 are (essentially) (t -1)A , generated 6

erated by {x 2y-2 z 2}.

by

{x 2y2, x 2 z- 2 }

and

«2+t +1)A 6 ,

gen-

It is easy to see that neither of these groups is

even normal in O(e )'. Therefore any abelian normal subgroup B

of O(e)

such that A6nB has rank less than 3 must map injectively to the abelianization, and so have rank 1. Such a group must be central. and (0(-) are

generated by

t3

and

t 6 x- 2 y 2z -2

In fact (0(+)

respectively. This com-

pie tes the proof of the theorem. 0

The group 0(+) is the group of the 3-twist spin of the figure eight knot. On the other hand, it can be shown that no power of a weight element is central in 0(-) and so it is not the ·group of any twist spin, although it is the group of a fibred 2-knot, by Theorem 9 of Chapter 2.

100

Ascending Series and the Large Rank Case

Nilpotent HP radical try to analyse rr'IT

We may

in a similar fashion when it has

r q for some q.

Hirsch - Plotkin radical isomorphic to

Let I be a PDt -group over Q

Theorem 9

with IIJ' ;:;' Z and which

has no nontrivial torsion normal subgroup. If the Hirsch -Plotkin radical H

of J' is isomorphic to r q

for some q

~

1 then

either J'

=

H

or the

quotient J'IH is isomorphic to Z/3Z or V. In particular, I is solvable, of derived length at most 4. Proof Let j

be an element of I

which is not in J'. Since H is normal in

I, the subgroup generated by Hand j is a poly-Z group of Hirsch length 4, and so has homological dimension 4. Therefore it has finite index in I (by [B: Theorem 9.22)) and so J'IH is finite. Let a:I-Aut(HICH) be the homomorphism determined by the conjugation action of I on H. Then H is contained in K = J' nker(a) and has finite index there. Since CH ;:;' Z, it is central in K and as HICH is central in KICH we may apply Baer's extension of Schur's theorem [R: 14.5.11 to

conclude

trivial. (by

that

[K,K'1

finite.

Since

it

is normal

in

is a nilpotent normal subgroup of J'

Therefore K

maximality

is

of

H).

a(J')

Since

is

a

finite

I, it must be and so K subgroup

H of

Aut(HICH) ;:;' GL(2,Z), it is cyclic or dihedral, of order dividing 24. Since it is the commutator subgroup of 11K it must admit a meridianal automorphism, and so must be trivial, Z/3Z or V. 0

We

shall assume henceforth that rr is

torsion free. Then rr' is

the fundamental group of a closed orientable Seifert fib red 3-manifold with a Nil-structure, by [Sc 19831 and [Z: Section 631. (Recall that Nil is the nilpotent Lie group of 3x3 upper triangular real matrices). These are either circle

bundles

over

the

torus

or have

fibres, of type (ai,Pi)' with !:.ai- 1

=

base

S2

and

3 or

4

exceptional

1. Each circle bundle over the torus is

the coset space of Nil by a discrete uniform subgroup isomorphic to for some q

~

r q'

1. We shall treat these cases first.

If is an automorphism of

r q , sending x to xaybzm and y to

101

Ascending Series and the Large Rank Case xC yd zn

for some a, . . . n

integral

A

matrix

in Z

~)

= (:

represents

r qlCr q = Z2 , and every pair Z2

an

determines

ordered

pairs

is

(A,~)

in GL(2,Z) and

to

GL(2,Z)

ker(p) ~ Z2.

On

which

(A,~XB,v)

messy:

(A,~)

sends

factoring

out

~

of

= (m,n) in

r q . The mul tiplica tion rule for such = (AB,~B+<detA)v+q

where w(A,B) is biquadratic in the entries of A

Aut(rq)

automorphism

induced

the

with A

automorphism of somewhat

to zad -bc. The

then it must send z

the

A

to

and B. is

w(A,B»

The map p from

a

homomorphism,

inner automorphisms,

and

represented by

q.ker(p), we find that Outer q) is a semidirect product of GL(2,Z) with the normal

(ZlqZ)2,

subgroup

[AB,~B+(detA)v),

where

[A,~)

with

multiplication

is the image of

given

(A,~)

by

[A,~)[B,v)

in Outer q).

=

In partic-

ular, Outer 1) = GL(2,Z).

Theorem

10

Let

7r

be a 2-knot group with

7r'

~

r q. Then q is odd

and the image of the meridianal automorphism in Outer q) is conjugate to [A,O), where A is one of

1) (11 -1)0' (11 01) or (01 -1). 1\ (1 2'

If

q > 1 only the latter two matrices determine meridianal automorphisms. (Moreover they represent mutually inverse automorphisms). Proof If

rq1crq

(A,~)

is

meridianal

then

so

are

the

induced

automorphisms

of

= Z2 and of z(rq/r q ,> = ZlqZ. Therefore Idet(A-I)1 = 1 and

detA-l is a unit modulo (q), so q must be odd, and detA = -1 if q > 1. The

characteristic

polynomial

of

such

a

2X2

matrix

must

be

one

X2_ 3X + 1 , X2_X+l, X2_X-l or X2+X_1. The corresponding fields

of

Q(.,fj)

and Q(v='J) each have class number 1 and so the conjugacy class of such a matrix is determined by its characteristic polynomial [New: page 52). Thus A

is

must be conjugate to one of the above matrices. The inverse of

[A -l,-(detA)~A -I),

so

[A,~)

[A,~)[A,v)[A,~)-l = [A,~+(detAXv-~)A -1)

[A,~(A -(detA)I)A -l+(detA)vA -lJ.

Since

A -(detA)I is

invertible,

[A,v)

is

conjugate to [A,O). (The remark in parentheses now follows as the latter two of the given matrices are mutually inverse). 0

102

Ascending Series and the Large Rank Case Every automorphism (A,J.I) of r q

is orientation preserving. This

follows, with some effort, from the criterion of [B: page 177]. Alternatively, any self homotopy equivalence of a nontrivial S1-bundle over an orientable surface of positive genus is orientation preserving [Fr 1975]. Each of the groups allowed by Theorem

10 is

the group of some

Theorem 9 of Chapter 2. We shall see q = 1 and detA

fibred 2-knot, by

in Chapter 8 that, except when

is positive, the knot realising such a group is unique up

to changes of orientation.

The group of the 6-twist spin of the trefoil

has commutator subgroup r l' In all the other cases the meridianal automorphism has infinite order and the group is not the group of any twist spin. Among the Nil -manifolds which are Seifert fibred with base S2 only

those

with 3 exceptional fibres of

type (3,Pi)' with Pi=±1, are of

interest to us, as in all other cases the quotient of the fundamental group by its Hirsch-Plotkin radical is cyclic of even order, and so the fundamental group does not admit a meridianal automorphism. (In particular, there is no 2-knot

group

7T

with

7T'

an

extension of

V

by

some r q)' Such 3-

manifolds are 2-fold cyclic branched covers of S3, branched over a Montesinos link K(O: b;(3,P1),(3,P2),(3,P3» [Mo 1973]. Up to change of orientation, that P1 = P2 = 1. If b

we may assume

does not admit a meridianal automorphism.

is odd then

the first homology

Therefore b must be even, and

so the link is a knot. These knots are all invertible, but none are amphicheiral [BZ: Chapter 12E]. (Among them are the knots 935 , 9 37 , 946 , 948 , 10 74 and 10 75 ), Let

7T(b ,£)

be

the

group

of

the

2-twist

of

spin

K(O: b;(3,l),(3,l),(3,£».

be a 2-knot group such that 1T' is a (torsion extension of Z!3Z by r q , for SOme q ~ 1. Then q is odd, and

Theorem

11

Let

isomorphic to 7T(q +2+£,£), for Some

Proof By the

free)

7T

£

7T

is

= ±1.

remarks above, we may assume

that 1T' is the fundamental

group Of the 2-fold cyclic branched cover of K(O: b;(3,1),(3,1),(3,£» for some even band

£

= ±1.

Therefore it has a presentation of the form

Ascending Series and the Large Rank Case

A Reidemeister-Schreier calculation normally generated

by

r b-2-E' Hence b

images

the

q+2+E, and q

shows

that

the

of rs- 1, rt -1

G

let

subgroup

of

index

3

is isomorphic to

and h

The centre of rr' is generated

is odd.

by

the image of h, and 3 . If we

103

1T'I u = r- 1s

has and

a

presentation v = sr- 1 we see

that G also has a presentation . Proof Clearly A has rank 1, and An T = zA. If TlzA ITIA

the

were infinite then

would have one end, and so H 2 (IT;O[ITJ) '" 0 [Mi 1986], contradicting theorem. Therefore ITlzA

is a finite

extension of 4>, and so zA

has

finite exponent, e say, by Lemma 3. Since eA is then a torsion free rank 1 abelian normal subgroup of IT the same argument shows tha t T must be finite, and hence trivial by Theorem 6 of Chapter 4. 0

106

Ascending Series and the Large Rank Case

The argument

for our next

theorem depends on an unpublished

result of Kropholler on solvable PD-groups over Q. Theorem

13

Let

be a

7T

virtually solvable 2-knot group witb maximal

locally - finite normal subgroup T. Suppose tbat 7TIT is a virtually poly-Z group of Hirscb lengtb 4. If

7T

also bas an abelian Dormal subgroup A

of rank> 0, tben it is a solvable PDt -group, and rr' is virtually

nil-

potent. Proof Clearly AnT - zA, so AlzA

is isomorphic to a

torsion free

sub-

group of 7TIT, and is thus free abelian. Theorems 3, 4 and 5 of Chapter 3 the'n imply that 7TlzA

is a PDt-group over Q. Since it is virtually solv-

able it must be virtually poly-Z [Kr 1987], and so zA has finite exponent, e

say, by Lemma 3. Since eA is a free abelian normal subgroup of

7T

of

rank > 0, the theorem follows from our earlier work. 0

When

is virtually nilpotent no assumption on abelian normal

7T'

subgroups is needed, and the classification can be made explicit. Theorem

14

Let

7T

be a 2-knot group witb virtually nilpotent commuta-

tor subgroup. Tben eitber and

£

=

±1, or

7T'

:::

7T

:::



from

to

Ext~+l(M.r> which are functorial in M. Similarly if A,. is the chain COmpie x 0

-

-

1\

1\

0 (concen t ra t ed in degrees 0 and

then there is a

1)

chain homotopy equivalence of A,. Qi) B,. with B,., and we obtain maps from Hq(B,.;f> to Hq+l(B,.;r> which are functorial in B,.. Suppose B j = 0 for j

now

the

above

H 1(B,.;I\)

is

B,.

-

complex

H 1(Hom r (B,.,I\»

as

7/

r-chain

free

the

{X in Home(Bo'Z) I

xa1

Ext ~ (Z ,I\)~HO(jj,.;Z)

Let represented

Z

= O}

by

such

that

a

H 1(B,.;I\)

of

the

[Ba

our

Hq +l(B,.;n

Hl(B,.;I\~Hq (B,.;f)

factors

through

pairing

Then

7/

is

the

of

analogous

1980'1.

from

in

class

~ Z. Now we may also

generator

under

from B,.

£,.

the

£l:Bl .... I\.

Ext ~ (Z,I\»

of

image

to

(=

be

7/

Ext~(Z,I\~HO(jj,.;Z) ;:; Z,

degree

complex

and there is a chain homomorphism

1\,

image of a generator of H 1(A,.;I\) obtain

a

< 0 and HO(B,.) = Z. Then the quotient map from BO onto

HO(B,.) factors through to

that

Since

pairing

from

Ext ~ (Z,I\) =

Ext~(Z,I\~Hq(B,.;f) and

we

may

to

identify

our

raising maps from Hq (B,.f) to Hq +l(B,.:n as those given by cup

product with

7/.

PD-fibratioDI If

the

homotopy

fibre

of

a

map

from

a

PDm -complex

to

a

PDn -complex is finitely dominated, then it is itself a PDm - n -complex. (For a nice proof in the case when all the spaces are homotopy equivalent to finite

complexes

see

[Go

1979]).

We

are

interested

in

obtaining

such

a

result for maps from PDt-complexes to S I, under weaker, purely algebraic hypotheses.

112

The Homotopy Type of M (K) Let E be a connected PDt-complex and let 0 S1 induces an epimorphism { .. :o

that the map {:E -

Then we may identify the homotopy fibre of {

"1(E). Suppose

=

-

with kernel H.

Z

with I!, the covering space

of E associated to the subgroup H, and we may recover E up to homotopy type as the mapping torus of a generator r.I! -

I!

of the covering group.

is a PDt -complex then it is finitely dominated [Br 1972] and so H

If I!

finitely presentable [Br 1975]. Moreover H .. (I!;Z) is then

must be almost

finitely generated and so X(E) "" O. We shall assume henceforth that these two conditions hold. Let C.. be the equivariant cellular chain complex of the universal covering

E.

space

HP(C.. ;r>

Then

H 4 _p

Since H 1(C.. ®rA) = H 1(I!;Z) "" HIH group,

E

of

0, and since

only nonzero homology modnles are HO(C.. ) = Z

abelian

[E]

=

complex by [Wa 1967]. So henceforth we shall assume and

from

is infinite HO(C,,:r>

0 also.

S3 (as in Theorem

are

Homr(H 1(C.®rA),A)

=

O.

An

and

-

is

a

is 1-

PDt-

is infinite,

0 also, so

the

n "" H 2(C.. ) = "2(E).

is fini tely generated as an

elementary

computation

then

shows that H1(C.:A) is infinite cyclic, and generated by the class 1/ introduced in the previous section. By Poincare duality for E with coefficients A the

H 3(I!;Z) "" H 3(C.. ®rA) is infinite cyclic, generated by Thus Hj(I!;Z) = Hj(C"®e Z ) 1/n[E]. Hj(C.. ®r A ) is fin-

abelian group

the class [I! ]

=

itely generated over Z

i

=

2.

-

and so is a torsion A-module, except perhaps when

On extending coefficients to Q(t), the field of fractions of A, we

may conclude that H2(C.. ®rA) has rank X(E) = 0, and so is also a torsion A-module. Poincare duality and the Universal Coefficient spectral sequence then imply that H2(C.. ®rA) ~ Ext ~ (H 1(C" ®rA),I\), and so is finitely generated

and

torsion

free

over

Z. Therefore I!

satisfies

Poincare duality

with coefficients Z, i.e. cap product with [I!] maps HP(C.;Z) isomorphically to H3_p(C.®eZ)

=

H3_p(C.. ®rA) [Ba 1980'].

The Homotopy Type of M (K)

113

By standard properties of cap and cup products, to show that I! satisfies Poincare duality

[I! I gives isomorphisms show that the map Tip cup product with

TI

with coefficients S, i.e.

HP(C.. ;S)

from

that cap product

H 3 _p 5 then the commutator sub-

is a classical knot

is as in the corollary, and M(T rK) fibres over S1. next

result

improves

upon

Corollary

3

of

Theorem

3

of

Chapter 3.

Corollary

3

Let M be a closed orientable 4-manifold with X(M)

and free abelian

=

°

fundamental group. Then M is homotopy equivalent to

S3 XS 1, S2XS 1 XS 1 , or S1XS 1 XS 1 XS 1. 0

It can be shown that any such manifold M

is homeomorphic to

one of these standard examples [Kw 19861.

Groups of finite geometric dimension 2 In dimension

this

section

2, deficiency

we

shall

1 and one

assume end.

that

has

G

finite

geometric

For any (left) r-module

N

let

e q N be the left r-module which has the same underlying abelian group as the right r-module Ext~(N,r) with the conjugate left r-module structure. Since c.d.G = 2, the ring r

q > 3. Moreover if rg -

has global dimension 3 and so e q N =

r -

the augmentation r-module

Z

-

° is

° for

a partial projective resolution of

then the kernel at

the left, L

say, is projec-

tive. Since G has a finite 2-complex as an Eilenberg-Mac Lane space and deficiency 1, we may assume that L is free of rank g -1. Since G has one end,

eO Z

resolution

e 1Z

°- r

=

e 3Z

-

e Oe 2 Z = e 1 e 2 Z

e 3e 2 Z

nonzero,

the

and

Aut(Z) = ±1.

by

° and so transposing this e2 ° for e 2 2 2 '" ° and e e Z In

rg _ rg -1

functoriality

Z

_

Z.

=

of

Z.

e 2 (_)

we

resolution gives We

e 2 Z is Aut(e 2 Z)

particular, have

a

then see that

The HomolOpy Type of M (K) Theorem 4

117

Let M be a closed orientable 4-mani[0Id witb X(M) = 0 and

sucb tbat G = "l(M) bas

finite geometric dimension 2, deficiency 1 and

one end. Tben "2(M) ~ e 2 Z, and tbe isomorpbism is unique up to sign.

Co -

0

be

the

cellular

chain complex of the universal covering space M. Then C. is a complex of finitely

generated

free

r-modules

left

whose

homology

H•

is

=

H.(M;r) = H.(}ii;Z). By Poincare duality and the Universal Coefficient spectral

e 2 H 2 == Z 0

Hj

sequence

and

=

j

unless

0

is

there

or

== 0

an

2,

sequence

exact

- - - - - - - - e 2Z

eOH

H2

e1H of

e 3 H 2 == 0,

2

left

r-modules

functor e .(-) to this exact

Applying the

O.

2

while

sequence, and writing P for eO H 2 , we obtain a twelve term exact sequence 0

e1p

that 0

e 3 e 3Z

eOp

e 2p

0,

e 2H

2

Using the above obse rva t ions, we find

O.

there and that 3 2 2 e p O. e e Z

submodule of a e 2H 2 = e 2 e 2 Z

free

tive, and so H2

P~e2Z.

module

and

r

an

is But has

exact

e 3p

global

Z, it follows that e 2 p == 0 also.

0

since

dimension

sequence

P

is

3.

Since

a

Hence P is projec-

Therefore we have exact sequences (1)

and (2)

where Z2 is the module of 2-cycles, which is projective, since (from (5» is a third syzygy. Now P~e 2 Z

also has a resolution of the form (3)

O.

Applying Schanuel's lemma to Z

given

above,

we

find

Z2~rg-l~cl~r = c2~rg~cO

it

(1)

and (3) and to (2) and the resolution of

c4~rg~z2 == r~c3@p~rg-l

that and

and

therefore

r~c3~rg -l~p~rg -l~cl~r. But X(M) == 0, so C4@C2~CO == C3~Cl. Thus

there

is

a

finitely

generated

free

r-module

F = c3~cl@r2g

such

that

118

The HomOlOpy Type of M (K)

= F~P. H2 = e 2 Z

This

F

implies

that

P = 0,

by

Kaplansky's

Lemma,

so

and the first assertion follows from the Hurewicz Theorem. The

isomorphism is unique up to sign since Aut(e 2 Z) - (±1). 0

Is this theorem still true under the formally weaker assumption that G has cohomological dimension 21 It is not yet known whether each such

group

has

geometric

dimension

(Cf.

2.

Theorem

of

6

Chapter

2).

Whether such a knot group has one end is related to the question of Kerva ire as

to whether a

nontrivial free

product with abelianization Z

can

have weight 1 [Ke 19651. Corollary 1 The cellular chaill complex of M(K) is determilled up to

chaill homotopy equivalellce over r by G.

Proof

There

are

exact

sequences

0 -

B1 -

C1 -

Co -

Z

0

-

and

n - O. Schanuel's lemma implies tha t B 1 is projective, since c.d.G - 2. Therefore C 2 ~ Z 2~B 1 and so Z 2 is also projective. Thus C. is the direct sum of a projective resolution of Z jective resolution of n ;;; e 2 Z

In

general

there

and a pro-

with degree shifted by 2. 0

may

be

an

obstruction

to

realizing

a

chain

homotopy equivalence between two such chain complexes by a map of spaces (cf. [Ba 1986».

Corollary

2

Let K alld K 1 be 2-kllots with group G.

3-collllected map f o:M(K l)-illt D4 f :M(K 1)

-

M(K), thell

f

M(K). If

f0

Theil there is a

extellds to a map

is a homotopy equivalellce.

Proof In each case H 3(G;"2(M» is trivial, since c.d.G "" 2, and so the first k -invariant is O. The existence of a map f

0

which induces isomorphisms on

"1 and "2 now follows as in Theorem 1. Since H 3UJ;Z) "" H 3(M;r) = 0,

"3(M)

= r W("2(M»

(where r W(-) is here the quadratic functor of White-

head [Wh 1950)), and therefore f

0

induces an epimorphism on "3' and so is

The HomolOpy Type of M (K) If

3-connected. homology

I

extends

of

the

=

0 for j

H/M(K);r»

10

then it must

universal ~

119

covering

induce isomorphisms on

spaces,

the

since

is a homotopy equivalence. 0

3. Therefore I

Thus the major task in determining the homotopy type of M(K) is to decide when 10 finitely

generated

extends. When 7fK is such a knot group and

then

it

must

be

free

[B:

Corollary

8.6J,

and

7f'

is

then

7f

determines the homotopy type of M, as we shall show next. Free kernel We shall now assume that G is an extension of Z generated

free

normal

subgroup,

and

shall

adapt

our

by a finitely

earlier

notation

without further comment. Theorem

5

Let M be a closed orientable 4-manilold with X(M)

and suppose that the map I:M G

=

7f 1 (M)

to Z

S 1 induces an epimorphism

with kernel H a

Iree group 01 rank r.

simple homotopy equivalent to a PL 4-manilold N with

fibre

which

I..

Then

=

0

I rom M is

fibres over Sl

#r(SlXS2) and which is determined up to PL homeomorphism

by its lundamental group G. Proof If r = 0 then the argument of Theorem 1 shows that M

is homo-

topy equivalent to S3 XS 1. Therefore we shall assume that r > O. Since G then has

a nontrivial finitely generated free

normal subgroup of infinite

index, it has finite geometric dimension 2, deficiency 1 and one end. Therefore n = e 2 Z, by Theorem 4, and so eqn = Z if q = 2 and is 0 other-

=

wise. In particular, Homr(n,r) e 2Z

=

Ext

f (Z,r)

is isomorphic to Ext

also have Ext~(ii,a) = Z sequence

for

0 and so 1/1 is an isomorphism. Moreover,

H"(C.. ;a)

if q

we

H3(c.. ;a) -;;; Z. Therefore

C..

then

J (Z ,a)

as a (left) a-module, so we

1 and is 0 otherwise. From the spectral find

that

H 2 (C.. ;a) = H 4(C.. ;a) = 0

and

is chain homotopy equivalent (over a) to a

complex which is concentrated in degrees 0, 1, 2 and 3. It then follows that the map from H 3(C.;€I) to H3(C.;Z) induced by the augmentation of €I

The Homotopy Type of M (K)

120 onto Z Z.

is onto, and so is an isomorphism, as each module is isomorphic to Similarly the map from H 4 (C.. ;r> to H 4(C.. ;/\) induced by the projection

of r onto 1\ is also an isomorphism. There is a commutative square

in which the vertical maps are the isomorphisms just described and the horizontal

maps

are

given

by

cup

product

H .. (C.. ;I\) is finitely generated over Z

Since H finite

is free, K O(H) =

PDt -complex.

simple

As

1/.

remarked

earlier,

and so the lower map is an isomor-

Therefore the upper map is also an isomorphism.

phism [Ba 1980'1.

a

with

Now

Wb (H) = 0 [Wa 19781 and so M

is

such a complex is determined up

to

homotopy type by its fundamental group and a class 1977). Therefore

is homotopy equivalent

M

t"

in H 3(ff 1(M );Z) [He

to ,T(S1XS 2 ). As every self

homotopy equivalence of ,reS 1XS2) is homotopic

to a PL homeomorphism

(which is unique up to isotopy [La 1974», M is homotopy equivalent to the mapping

torus

of

N

such

a

homeomorphism.

Finally

any

such

equivalence is simple, as G is in Waldhausen's class Cl and so

homotopy Wb (G) "" 0

by Theorem 19.4 of [Wa 19781. 0

If K

is

the

Artin spin of a classical fibred

knot

then

M(K)

fibres over S1 with such a fibre. However not all such fibred 2-knots arc: obtained in this way. (For instance, the Alexander polynomial need not be symmetric [AY

1981». A problem of interest

here

which

was

raised by

Neuwirth [N: Problem PI and is still open is: which groups are the groups of classical fibred knots? Apart from the trefoil knot group and the group of the figure

eight knot

rank 2 and GIG'

=

Z

there are just

two groups G

with G

ciency 1 they are 2-knot groups. So also is

the group with presentation

<x,y I x 2 y2x2 = y> which is the group of a fibred knot in

homology 3-sphere M(2,3,1l), but which is not knot [Ra 19831.

free of

[Ra 19601; as they each have weight 1 and defi-

the Brieskorn

the group of any classical

The HomolOpy Type of M (K)

121

Quasifibres and minimal Seifert hypcrsurfaces Let M be a closed orientable 4-manifold and

f:M -

S 1 a map

an

epimorphism

f.

transverse over p

in Sl. Then

? =

f -l(p) is a codimension 1 submanifold

N

?X[ -1,11.

which

with

induces

a

product

o± W

neighbourhood

from

!:>
maps Z

4>

may

be

viewed

as

an HNN

its subgroup 2Z. It is

onto

extension

therefore in

4> =

Waldhausen's

class CI, and so Wh(4)) = O. This is also true of knot groups with and of all classical knot groups example of a finitely

presentable

tWa

19781.

torsion free

(In fact

z .. 4>'

TT'

free,

there is no known

group which has

nontrivial

Whitehead group). Theorem 6

Let M be a closed orientable 4-manifold with

group 4>. Then any homotopy equivalence

fundamental

f:N ... M is homotopic to a

homeomorphism. proof Although

4>

is

not

square

root

closed

accessible, Cappell's

splitting

theorem holds for it, by the remark on page 167 of [Ca 19761, so there is still an exact sequence

L (Z) ... L (Z) ... L 5(4)) ... L 4 (Z) - L 4(Z) where 5 5 the extreme maps are essentially l-L .. (4)). (Cf. pages 498 et seq. of [Ca

140

Applying Surgery 10 Determine the Knot

19731, or [St 1987]). Since L 5( to Z induces a map to the corresponding exact sequence lor Z, considered as an HNN extension of the trivial group. A diagram chase now shows that

L 5(4))

L 5(Z) = L 4(1) = Z

to

is

isomorphism.

Similarly

L 4(4)) =

is s -cobordant to id M' and

2 the map f

L 4(Z) = L 4 (1). Now by Lemma

so f

an

the induced map from

is homotopic to a homeomorphism. 0

Corollary A

ribbon knot K with group 4> is determined up to orientation

by the homotopy type of M(K). Proof Since 4> is met abelian, there is an unique weight class up to inversion, so the knot exterior is determined by M(K), and since K is a ribbon knot it is determined by its exterior. 0

This

corollary

applies

in particular

to Examples

10

and 11

of

Fox [Fo 19621. Ribbon 2-knots are -amphicheiral, but no 2-knot with an asymmetric Alexander polynomial can be invertible. Thus as oriented knots these examples are distinct. Is there a 2-knot with group 4> which is not a ribbon knot? Theorem 7 Let K be a 2-knot such that

Then K is s-concordant to a

TT'

is a

free group of rank r.

fibred knot with closed fibre #r(SlXS2),

which is determined (among such fibred knots) up to changes of orienta lions by

such

TT

together with the weight orbit of a meridian. Moreover any

fibred knot is reflexive and homotopy ribbon.

Proof By Theorem 5 of Chapter 7 M(K) is simple homotopy equivalent to a PL 4-manifold N which fibres over Sl with fibre #r(SlXS2), and which is determined among such manifolds by its group. As the group

TT

is square

root closed accessible, abelianization induces an isomorphism of L .. (TT) with L .. (Z).

Therefore by Lemma 2 there is an s -cobordism

We may embed an annulus A a meridian for K

= Sl X[O,11

in Z

to such a fibred knot

from M to N.

so that MnA .. Slx{O} is

and NnA = Sl X{l}. Surgery on A

s -concordance from K

Z

K l'

in Z

which is

then gives an reflexive [Gl

Applying Surgery to Detennine the Knot

141

1962] and homotopy ribbon [Co 1983]. 0

Corollary The O-spin of an invertible

fibred knot is determined up to

s -concordance by its group together with the weight orbit of a meridian. Proof The O-spin of a classical knot is -amphicheiral and reflexive. 0

If the 3-dimensional Poincare conjecture holds then every fibred

2-knot with

TT'

free is homotopy ribbon [Co 1983]. Is every such group the

group of a ribbon knot?

142 Appendix A

Ponr-Dimensional Geometries and Smooth 2-Knots

A smooth 2-knot is a smooth embedding K of S2 into a smooth homotopy 4-sphere Eo

The manifold

M(K) obtained

by surgery on K

is

then a smooth orient able 4-manifold, and if it fibres smoothly over Sl we shall say

that K

supports

a

is a smoothly fibred 2-knot. In a number of cases

4-dimensional geometry.

There

are

in

fact

19 classes

M

of 4-

dimensional geometries. In the light of the role that algebraic surfaces are currently that

playing

some of

in 4-dimensional differential

these

manifolds in fact

admit

of

interest

nonsingular complex

topology

it

is

analytic

structures. (These cannot be algebraic or even Kihler, as P1 (M) is odd. See [Wa 1986] and the kiewicz,

Inoue,

references

Kato

and

there, in particular to

Kodaira,

for

more

the work of Filip-

details

on

4-dimensional

geometries and complex surfaces). If K

then M

is a branched twist spin of a torus knot or a simple knot

fibres over Sl with fibre a closed irreducible 3-manifold with a

geometric structure (of type S3, SL, Nil 3, H3 or E3) and monodromy having finite order and nonempty fixed point set. The manifold M finite

cover

which

has

the

corresponding

4-dimensional

then has a

product

geometry

(S3 XE 1, etc.), and so M admits this geometry alone, if any at all. We shall show

that

the

only

other geometries

manifolds M(K) are Sol ~, Sol

t

that

may

be

realized

by

such

4-

and Sol,!,m±l for 2m±1 ~ 11, and possibly

H4 or H 2(C) (although we know of no examples of the latter types). A closed 4-manifold admits at most one geometry, and homotopy equivalent

geometrizable

manifolds

must

have

the

same

geometry,

by

Theorem 10.1 of [Wa 19861. The 4-dimensional geometries not already mentioned are

S2XS2, S2XE2, S2XH2, E2XH2, H2XH2, S4, p2(C), Nil4. and

F4. The last of these cannot be realized by any closed 4-manifold, and so

cannot occur here. Since the universal cover geometries S2XS2, S4

and

M

is an open 4-manifold the

p2(C) cannot occur. If

M i~

not contractible

then the geometry must be a product geometry, S2XE2, S2XH2 or S3 XE1. Of these, only S3 XE 1 admits discrete uniform actions of groups with infinite cyclic abelianization. All of the remaining geometries have contractible models. Most of the geometries of solvable type can be realized by smooth 2-knots with

Four-Dimensional Geometries and Smooth Knots M

aspherical and "

solvable. The results below in such cases follow

our determination of conjunction with

143

the

virtually

torsion free

from

solvable 2-knot groups in

the description of the discrete

uniform subgroups of

the

isometry groups of the solvable 4-dimensional geometries given in Section 2 of tWa 1986). If M has a geometry of type S3 XEl then "' is finite and

M

is

R 4 -{a}. If M is a complex surface (compact com-

diffeomorphic to S3 XR

plex analytic manifold of complex dimension 2) and "' is finite then M is a Hopf surface, i.e. over M cyclic,

is

T(1)

is analytically isomorphic to C 2 -{O} (Kodaira). More-

M

then determined up

to diffeomorphism by", and "'

must be

or /- (Kato). If M has a geometry of type E4 (i.e. is flat) then it is deter-

mined up to diffeomorphism by", which is virtually Z4. Since " isomorphic to

G(+)

or

G(-),

must be

there are just two such manifolds. Neither sup-

ports a complex structure. If M

has a geometry of type

Nil 3 XEl

then it

is fibred with

fibre of Nil 3 type and monodromy of finite order, and so is diffeomorphic to

M(K 1)

where

K 1

is

either

the

2-twist

spin

of

a

Montesinos

knot

KCOI b;(3,l),(3,l),(3,±I» for some odd b or the 6-twist spin of the trefoil knot. These manifolds admit complex surface structures as secondary Kodaira surfaces. The

discrete

uniform

subgroups

abelianization if and only if m -D

of

Sol,! ,D have

infinite

cyclic

±1. The manifold M(K) has a geometry

of type Sol,!,m±1 if and only if K is a Cappell-Shaneson knot and all the roots of its Alexander polynomial are positive, in which case 2m±1 ;;. 11. If K

is a Cappell-Shaneson 2-knot whose Alexander polynomial has one posi-

tive root and two negative roots then M(K) admits no geometric structure, but its 2-fold cover has a geometry of type Sol,!,D for some m, D. These manifolds do not support complex structures. However Shaneson knots

the

geometry of type Sol of

type

SM'

six

distinct

manifolds

arising

from

whose Alexander polynomial has only one

(Cf.

J,

the real

Cappellroot

have

and all admit complex structures as Inoue surfaces

Section

9

of

[Wa

1986».

These

manifolds

may

be

Four-Dimensional Geometries and Smooth Knots

144

distinguished by the Alexander polynomials of the corresponding 2-knots (cf. Table 1 of [AR 1984]). If M has a geometry of type Sol

t

then it is fibred, with fibre

a coset space of Nil 3 and monodromy of infinite order. One such manifold has

a

family

of complex

structures

as

an

Inoue

surface

of

SJ,t'

type

depending on a complex parameter t; the others form an infinite family, all having complex structures as Inoue surfaces of type S

N'

This family has a

"universal" member: each surface is a quotient of the universal surface by a free action of a finite cyclic group of odd order. Since any discrete uniform subgroup of Nil4 has abelianization of rank at least 2, this geometry cannot occur.

M

If

is contractible but

IT

is not

solvable

then the geometry

must be one of H 4 , H 2(C), H3 XEl, SLXE 1, H2XH2 or E2XH2. The last three of these do not infinite

cyclic

admit discrete uniform actions of any group with

abelianization,

and

geometry of type H4 or H3 xE l

so

cannot

occur.

No

manifold

with

can be a complex surface. (According to

Bogomolov, the Hopf and Inoue surfaces are the only nonelliptic complex

PI = 1 and P2

surfaces with Any

M(K)

= 0).

admitting one of the above geometries other than H4

or H 2 (C) is fibred, with

fibre a geometric 3-manifold. The TOP classification (up to Gluck reconstruction) of the knots of type Nil 3 XEl, E 4 , Sol04,

Sol

t

and So/,!,m±1 given in Chapter 8 then gives also the smooth classifi-

cation. In the present context however it is natural

to require that

the

weight class be represented by a cross-section of the (geometric) fibration. (Recall

also

that

monodromy has

by

finite

Plotnick's

theorem

any

order and nonempty

fibred

2-knot

fixed point

set

twist spin, if the 3-dimensional Poincare conjecture is true).

whose is

closed

a branched

145 AppcndiI B

Reflexive Cappell-Shaneson 2-Knots

Let replacing A The

be

A

characteristic

where a

a

matrix

in SL(3,Z) such

that

polynomial

of

is

On

det(A -1) = ±1.

by its inverse if necessary, we may assume that det(A -1)

..

1.

[ (X) .. X3- aX2+(a -OX-1 a ' is the trace of A. It is easy to see that fa is irreducible and A

then

has either 0 or 2 (distinct) negative roots. We shall assume

that

fa

has

one positive root Al and two negative roots A2 and A3. (This is so if and only if a is negative). Since the eigenvalues of A are distinct and real, there is

a matrix

P

in GL(3,R) such

A

that

= PAP- 1

commutes with

A

is

the diagonal

then jj .. PBP- 1

matrix diag[Al'A 2 ,A 3 ]. If B in GL(3,Z) commutes with A

and so must also be diagonal (as the A;'S are distinct).

Suppose that jj = diag[P1,P2,P3]. Then the criterion of the footnote in [CS 1976] for a 2-knot with rr' = Z3 and meridional automorphism A

to be

determined by its exterior is that P2P3 should be negative. On replacing B by -B if necessary, we may assume that detB = 1 and the criterion then becomes

PI < O. Let

F

be

the

field

integers in F. We may view

O[X]/(f a)

0 3 as

and

let

be

OF

the

ring

of

a O[X]-module, and hence as a 1-

dimensional F-vector space via the action of A. If B in GL(3,Z) commutes with

A

preserves

then a

it

induces

lattice,

detB = NF10(u(B».

itself

arises

in

(Note

however

this that,

and

an so

automorphism determines

Every unit way. for

a

of unit

which maps

In particular, instance,

this

this

the is

vector

u(B)

of

space

OF.

which

Moreover,

image

of

so

OF .. Z[X]/(f a).

if

Z[X]/(f a)

[ -22 = (X-2)3+7(X-2X4X+3>+7 2

is

to

in

the square of a maximal ideal of Z[X] and so the ring Z[X]/(f -22) is not integrally closed [Hi 1984 D. Let u be the embedding of F in R in F

which sends the image of X

to AI. Then if P and B are as above, we must have u(u(B»

Thus if the criterion of [CS 1976] holds, there is a unit

u

=

Pl.

in OF such

that NF10(u) = 1 and u(u) < O. Conversely, if there is such a unit, and if OF = Z[X]/(fa) then there is such a matrix B.

146

Relexive CappeU·Shaneson 2·Knots We may reduce the question of the existence of such a unit to

a standard problem of number theory as follows. Let U be the group of all units of OF' let UU be the subgroup of units whose image under U is positive, let U+ be the subgroup of totally positive units, and let U 2 be the subgroup of squares of units. Then U ~ (±l)XZ 2, since F is a totally real cubic number field, and so UIU 2 has order 8. The unit -1 has norm -1 and the element Al is a unit of norm +1 in UU which is not totally

positive (since its conjugates are A2 and A3). It is now easy to check that there is a unit of norm +1 which is not in UU if and only if U+ = U 2 , i.e. if and only if every totally positive unit is a perfect square in U. When the discriminant of fa

is a perfect square in Z, the field

F is Galois over Q, with group z/3Z. If moreover the class number of F

is odd, then U+ = U 2 , by [AP 1967]. In particular, if A

has

trace

-1

then the characteristic polynomial has discriminant 49, the ring Z [X1/( [ -1) is the full ring of integers, and the class number is 1 (cf. [AR 1984 D, so the corresponding 2-knot

is determined by its group, up to a

reflection.

(In this case the polynomial [ -1 determines the conjugacy class of A, by the theorem of Latimer and MacDuffee [New: page 521, and so determines the group among metabelian 2-knot groups).

147 Some Open Questions In

the

tradition of

[N]

and

[GK], we list here a

questions which we have not been able to settle.

number of

Of course some of these

questions are well known to be very difficult. 1. Is the Disk Embedding Theorem valid over arbitrary fundamental groups?

In particular, are s -concordant 2-knots isotopic? 2. What can be said about smooth

2-knots? In particular, is every fibred

2-knot isotopic to one which is smooth in the standard smoothing of S4? 3. When is a 2-knot fibred? Is this so if it has a minimal Seifert surface and the knot group has finitely generated commutator subgroup? 4. Is every PD 3 -group with nontrivial centre the fundamental group of a Seifert fib red 3-manifold? 5. Is every PD 3 -complex X such that e("l(X» 6. Le t N be a 3-manifold, and

~

CD

a connected sum?

a homotopy 3-cell in N such tha t

contains no fake 3-cells. Can every self homeomorphism of N so as to leave

~

N-~

be isotoped

invariant? In particular, is this so if N is either aspheri-

calor has free fundamental group? 7.

Let

M

be

a closed 4-manifold with

"3(M) be finitely

generated?

(If

X(M) =

0 and "2(M) = O.

so then e("l(M»

Must

1 or 2, and so either

M is aspherical or it is finitely covered by S3XS l).

8. Let M a

be a closed 4-manifold with X(M) = 0 and such that "l(M) has

finitely

presentable

corresponding

covering

normal space

a

subgroup

H

PD 3 -complex?

wi th In

quotient

Z.

particular, if

Is

the

e(H) =

1

must M be aspherical?

9. Le t M

be a closed orient able 4-manifold and f:M ... S 1 a map which

induces an epimorphism on fundamental groups. When can

[

be homotoped

148

Some Open Questions

to a map

transverse over 1 in SI

and such

that one (or both) of the

pushoff maps from F = [ -1(1) into M -FX(-E,E) induces a monomorphism on fundamental groups? 10. Is the homotopy type of M(K) uniquely determined by "K if c.d." = 2? In particular, is this so when " ~ ? 11.

Is

there

a

2-knot

K

such

that

M(K)

is

contractible

but

Dot

homeomorphic to R 4? 12. Is every 2-knot uniquely factorizable as a sum of irreducible knots? 13. Is every homotopy ribbon 2-knot a ribbon knot? In particular, is every 2-knot group " with "' free the group of a (fibred) ribbon knot? 14. If the group " of a fib red 2-knot has deficiency 1, must "' be free? 15. Show that if r > 2 the r-twist spin of a nontrivial I-knot is never reflexive. 16. If the centre of a 2-knot group is nontrivial, must it be Z/2Z, Z, Z(i}(Z/2Z) or Z2? Is the centre of the group of a 2-link with more than

one component always trivial? 17. Must a virtually locally-finite by solvable 2-knot group with one end be torsion free? 18. Is there a 2-knot group which has a rank 2 abelian normal subgroup contained in its commutator subgroup? 19. If a 2-knot group " has a rank 1 abelian normal subgroup A

such that

e("IA) = 1 must it be a PDt-group?

20. Is every 3-knot group which is a PDt-group in which some nonzero power of a weight element is central the group of a branched twist spin of a prime classical knot?

Some Open Questions

149

21. Does either of the conditions "c.d.G other,

G

when

is

a

finitely

=

presentable

=

2" and "del G group

with

imply

J.l"

~ ZJ.l

GIG'

the and

H 2(G;Z) = O?

22. If the commutator subgroup of a 2-knot group is finitely

generated,

must it be finitely presentable? coherent? 23. Which A-modules and torsion pairings are realized by HI (X(K);A)

for

some 2-knot K? 24. Find criteria for a 2-knot to be doubly slice. In particular, must a 2knot with rr'hr"

finite and hyperbolic torsion pairing be TOP doubly slice?

A related question is: does every rational homology 3-sphere with hyperbolic linking pairing embed (TOP locally flat) in S4? 25. What can be said about the fibred 2-knots which are the links of isolated singularities of polynomial maps from R 5 to R 2? 26.

Determine

the

smooth

2-knots

such

K

that

M(K)

admits

a

4-

dimensional geometric structure. 27. Let G

be an extension of Z

by

the fundamental group of a closed

orient able 3-manifold which is hyperbolic or Haken. Is Wb(G) = O?

28. Compute

Wb(rr)

and L~(rr) when rr is an extension of Z

by a finite

normal subgroup with cohomological period 4. 29. If G

is a finite group with cohomological period 4 there is a (finite)

orientable PD 4-complex with fundamental grOup GXZ and Euler characteristic O. When is there such a closed 4-manifold? (Such a manifold can fibre over SI only if G is a 3-manifold group).

30. Determine the finite homology 4-sphere groups. In particular, is I-Xlone such?

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