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Annals of Mathematics Studies Number 56
ANNALS OF MATHEMATICS STUDIES Edited by Robert C. Gunning, John C. Moore, and Marston Morse I.
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and N.
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C a r l L u d w ig S i e g e l
and
B o ch n er
K . C h a n d rasekh aran
20. Contributions to the Theory of Nonlinear Oscillations, Vol. I, edited by S. 21. Functional Operators, Vol. I, by
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W.
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M o rse,
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B.
A.
K N O T GROUPS BY
L. P. Neuwirth
PRINCETON, N E W
JERSEY
P R I N C E T O N U N I V E R S I T Y PRESS 1965
Copyright © 1965, by P r i n c e t o n U nive r s i t y P ress All Rights Reserved L. C. Card 65-14393
Printed in the United States of America by W e s t v i e w P ress ,Boulder, Colorado Princeton U
niversity
P ress O
n
D
emand
E di t i o n ,1985
CONTENTS CHAPTER Is
INTRODUCTION § 1 . Introduction................................
CHAPTER II:
NOTATION AND CONVENTIONS § i. Introduction............... .................. §2. Group Theory .................................. §3. Geometric Conventions...........................
CHAPTER Ills
CHAPTER IV:
CHAPTER V:
.
COMBINATORIAL COVERING SPACE THEORY FOR 3-MANIFOIDS § i. Introduction.................................. §2. Computation of from a Maximal Cave......... §3. The Splitting Complex........................... H. A Splitting Complex for a K n o t ................ $5. Construction of Coverings from a SplittingComplex THE COMMUTATOR SUBGROUP AND THE ALEXANDER MATRIX § 1. Introduction.................................. §2. An Orientable Surface Spanned by a Knot......... §3. The Infinite Cyclic Covering of a K n o t ........ §U. A Property of the Surface of Minimal Genus . . . . §5. The Structure of the CommitatorSubgroup of a Knot Group.................................. §6. The Alexander Matrix (tentativeDescription) . . . §7. The Alexander Polynomials...................... §8. The Alexander M a t r i x .......................... §9. The Alexander Polynomial....................... SUBGROUPS § 1. Introduction.................................. §2. Kernels of Maps to ZR ......................... S3. §k . §5. §6. §7.
V ..................................... Abelian Subgroups.............................. Homology of Subgroups........................... Commutator and Central Series................... Ends ..........................................
v
1
5 5 6
9 9 12
13 15 25 25 26 27 29 3U 3U U2 1*6
U9 U9 51 56 58 59 59
CONTENTS CHAPTER VI:
CHAPTER VII:
REPRESENTATIONS § 1 . Introduction................................ §2 . Metacyclic Representations.................. §3. Non-trivial Representations of Non-trivial E l e m e n t s ................................ §1*. The Range of Finite Homomorphs............. . AUTOMORPHISMS § 1 . Introduction................................ §2 . Outer Automorphisms.......................... §3. Symmetries..................................
CHAPTER VIII: A GROUP OF GROUPS § i. Introduction................................ §2 . The Semi-group of Knots...................... §3. Some Axioms.................................. §U. A Binary Relation............................ §5. Some Examples................................ §6 . Amalgamations................................ §7. Knot Groups.................................. CHAPTER IX:
CHAPTER X:
CHAPTER XI:
THE CHARACTERIZATION PROBIEM §i. Introduction................................ §2 . Necessary and Sufficient Conditions........... §3. Sufficient Conditions........................ §1*. Necessary Conditions........................ THE STRENGTH OF THE(H*OUP § 1 . Introduction................................ §2 . Homotopy Type................................ §3. The Topological Type of the Complement of a Knot...................................... §U. Knot Type. . .............................. PROBLEMS § l. Introduction................................ §2 . Problems....................................
61 61
63 6^ 67 69 72 75 76 77 78 81
83 8^ 87 87 90
91
93 93
97 99 99
APPENDIX by S. Eilenberg........................................
103
BIBLIOGRAPHY...................................................
107
INDEX
113
. .
....................................................
vi
CHAPTER I INTRODUCTION § 1 . Introduction
The relations between topology and group theory have always been cordial at the very least, and this book is meant to take advantage of that fact.
This work is intended to give some indication of the present state
of knowledge concerning the fundamental group of the complement of an arbi trary polygonal knot in the three sphere.
The relation of such a group to
"group theory" on the one hand, and to the problems of three-dimensional manifolds on the other is an interesting one. The homology groups of aknot group vanish in dimensions bigger then two, so that in a sense a knotgroup
is close to being free.
But,
what is more to the point, the knotgroup
arises in a natural way from a
geometrical situation, and this situation permits the application of a good many geometric techniques. and suggest algebraic techniques.
These ‘techniques lead to algebraic results, So that, just as, classically, an ab
stract group theory arose from geometric considerations, one may hope that more sophisticated geometric attitudes will enrich group theory.
Now re
cent results concerning three-dimensional manifolds have considerably ad vanced our knowledge , and the work of Wallace [67], and Lickorish [3^1, as well as the older work of Alexander [1 ], have placed knot theory in a more central location with respect to the theory of three-dimensional mani folds.
I hope to present the reader same of the knot theory having to do
particularly with the group of a knot.
It will be seen that the geometry
of the situation can rarely be ignored, and the interplay between algebra and geometry should be apparent. 1
I . INTRODUCTION
2
Of fundamental importance to this presentation is the concept of a covering space.
In order to present this idea coherently, I find it con
venient to develop a theory of covering spaces of three-dimensional mani folds from a purely combinatorial point of view.
This theory arises from
an algorithm for computing a presentation of the fundamental group of the complement of a (possibly empty) one-dimensional subcomplex of a triangu lated three-dimensional manifold.
While a more general approach would have
been possible, there seemed to be no need here to consider dimensions bigger than three. One might adopt the view that a knot group is simply a peculiar special case of a group having a presentation of the following sort
(x,
V
Xj x'*J -
xj+1)
This is shown for example in [5*0.
J - 1 , 2,
. ± 1
n-i,
.
One may also derive the existence of
such a presentation from results in Chapter III.
This point of view may
occasionally prove fruitful, but I have not been able to utilize it often enough in this book to make such a position worthwhile.
It should not,
however, be ignored as a possible entree into the subject. Material which has not appeared elsewhere includes all of Chapters VIII and III, and practically all unreferenced theorems. Proofs are not given for all the theorems presented.
Proofs are
given when the methods of proof are interesting, or when the proofs have not appeared elsewhere.
Occasionally a proof has been omitted because I do
not understand it well enough to present it. The reader familiar with knot theory will find at least the following omitted:
Trotter's work on the cohomology of knot groups [63),
the fascinating results of Crowell [8 ], Murasugi (39), and Kinoshita [3i1 on alternating knots, an exposition of a good deal of Crowell's recent in vestigations into the structure of the commutator module [9 ), Seifert's computations concerning the Alexander matrix [57), the relations between knots and braids, a discussion of the Stallings Pibrations [59), and final ly links.
§1 .
INTRODUCTION
3
I thank Professors Pox, Papakyrikopoulos, Trotter, Stallings and Crowell for their generous help in the preparation of this manuscript. The invaluable assistance of Peter Strom Goldstein is also grate fully acknowledged. Finally, I wish to thank both Professor Gunning for his confi dence and cooperation, and the Institute for Defense Analyses, whose atmos phere and encouragement provided a great stimulus for working on this material.
CHAPTER II
NOTATION AND CONVENTIONS
§ 1.
Introduction
While most of the material in this chapter is a formality, there are some mildly unusual uses of familiar terminology.
The careful
reader is recommended to read § 3 of this chapter before reading Chapter III.
§2 . Group Theory
G subgroup.
will commonly denote a knot group and
However, [H, H]
and
H1
denote the commutator subgroup of
G ! Its commutator
will be used interchangeably to H.
Frequently reference will be made to a free product with amalgamation.
We denote such a construction A * B, and depend upon the C surrounding context to supply the information about the amalgamating maps
C -*• A,
C
B.
ample in [33].
The formal construction of A * B may be found for exC There one also may find the main properties that will be
used here. Where confusion might arise we adopt the usual notation (X,, ..., X jj j r,, ..., rm )
and
|x,, ...,
; r, , ..., r j
to distln-
guish the presentation of a group from the symbol denoting the group itself. The deficiency of a presentation is the number of generators minus the number of relations. 5
6
II.
NOTATION AND CONVENTIONS
The cyclic group of order
n
is denoted
The infinite cyclic group is denoted ^ - ♦ F - * - G - ^ Z - *' 0
When a situation G,
of the non-abelian group
F,
Z.
arises, (the extension, 1 , by the infinite
with identity
cyclic group) we will frequently refer to a generator have as if
t c G.
t
such that
a ( 5 ( a a ) ) ,
cpb ( 8 ( a b ) ) )
q>b (5 (ab )))
.
maps a to b .
This construction leads to a rule telling you which copy of
M
you walk into when you are in a copy of M and you cross a 2-simplex corre sponding to a 2-simplex of K.
This means we may associate to a path in M,
and a sheet M& , a path in our identification space, by walking along a copy ing path which starts in Ma and enters a different sheet when our assignment says to (recalling the process of analytic continuation). Now remove from this identification space all 1 -simplices which are mapped onto
L
by the various
cp& .
18
III.
COMBINATORIAL COVERING SPACE THEORY FOR 3-MANIFOILS
Having performed all the identifications and removals we were supposed to, we denote by from
M
to
M-L
M
the resulting space, and by
induced by the mappings
consider the open 3 -simplices of THEOREM 3.5.1. M. PROOF.
S
to be contained in
(M, «)
Obviously, •
1 . If
M-L,
M&
*
the mapping
q>a . In what follows we may M.
is a covering space of
is continuous and maps
M
onto
M.
is a point in the interior of a 3-simplex of
then the interior of that 3 -simplex is evenly covered by a copy of
that 3 -simplex in each copy of 2 . If
S
M.
is a point in the interior of a 2-simplex,
E,
then the (open) coboundary of that (open) 2 -simplex is a neighborhood of S
that is evenly covered.
owns a copy of M
BE,
For if
while if E
are incident along a 2-simplex
copy of
M
owns a copy of
tion assigned to
E, 3.
not contained in having covered.
T
BE,
E is not in
is in
K
S
E* mapped by
$ into
E,
S
beginning In a 3-simplex
r1
a € A
the successive images of the 2 -simplices in
s(T)
T
3 1 € A,
fixing
L
then we may denote by
, a2,
sets of the form
cr
« n+1
induced by the permutations corresponding to lying in
K,
and the ordering of the coboundary
crn+1 =
Byour condition
a . Now for each selection of an index
there is induced in this way a unique sequence
..., 8n . Furthermore, if the interior of
along a small
i^, r2, ..., r ,
of these 2 -simplices induced by our little oriented loop. on permutation assignments
M-L
and not intersecting any
i-simplices, we pass successively through 3 -simplices, If we select an index
T,
which is evenly
This may be shown as follows, if we run around L
or a single
is a point in the interior of a 1 -simplex
on their boundary is a neighborhood of
oriented loop
M
M.
then the set of all (open) 3 -simplices in
L,
of
depending upon the action of the permuta
on the index of the copy of If
K theneach copy
either two distinct copies of
Ui_1 0,
r1
U r2
^ P1#
aj ^ 0 j •
P2,
follows from this that
is evenly covered by the interior of the disjoint 0
U *** U rnn , where
0i
Is the unique
§5.
19
CONSTRUCTION OP COVERINGS PROM A SPLITTING COMPLEX
3 -simplex in
M^
lying over k.
r^.
Suppose now that
s
Is a vertex in
M-L.
M -L
is a manifold, the star of
s
3 -ball
whose boundary is a triangulated 2 -sphere which
B
(containing
we denoted by
H,
s)
is a triangulated 3-ball.
As
the triangulation being induced by the 2 -skeleton of
Name the 3-simplices having s as a vertex ai ~ 3 -simplex A 1 in Ma lying over A 1 .
may be reached by a path on
,
H.
H
starting in
M.
A ^, Ag, ..., Am . Select a
The interior of any other 3 -simplex,
2 -simplices in
Select a smaller
Ar,
A}
in the star of
s
and intersecting only
Such a path determines a sequence of indices,
ce1, 0^ ,
as it passes from one 3 -simplex to another through 2 -simplices.
These indices are the sequence of images of
cr. determined by our permu-
tation assignment.
over
determination of A1
to
Now having selected A. aH
Ap
over
Ap
isindependent
Ap . This is true because two paths
A.,
we claim that the
ofthe pathchosen from
a,and P
from
A1
to
Ap
determine a loop
L = crp- 1
0 -skeleton of
may be deformed in the complement of the o-skeleton of
H,
H
and any loop
L
on
H not intersecting the
into a product of loops encircling each vertex of
of these loops induces the identity permutation on selection of an index
a1
and a 3 -simplex
neighborhood of a preimage of
s.
A1
A.
H
once, and each
This shows that the
determines uniquely a
By our construction, any identification
of vertices arises from an identification of some pair of 2 -simplices having these vertices on their boundary, so that the neighborhoods deter mined by distinct star of
s
a 1 and fixed
A1
are disjoint and the interior of the
is evenly covered by a set of neighborhoods which may be in
dexed by the elements of
A.
This completes the proof of the theorem.
At this point a splitting complex for for two ends; first to obtain a presentation of obtain certain coverings of
M-L.
(M, L)
has been utilized
ir^M-L),
and secondly to
We will unify these two uses by means
cf the following theorem, which we must prove to show the utility of this combinatorial theory.
20
III.
COMBINATORIAL COVERING SPACE THEORY FOR 3-MANIFOLDS THEOREM 3 .5 .2 . [Fundamental theorem of Covering Space Theory; (for combinatorial 3 -manifolds with a i-dimensional subcomplex removed) .3 To every subgroup, S C ^((M-L), o) there corresponds a combinatorial covering space (M, ) there corresponds a subgroup S C ^(M-L) such that
PROOF. Theorem 3.5.1
*(*! (M)) = S.
A combinatorial covering is a classical covering by
so the second part of the theorem is true.
Let
K
be a splitting
Suppose
complex for
S C it^CM-L), o)
interior of a 3 -simplex.
Let
Now according to Theorem 3.3.1 pair of 3 -simplices in
5 (E)
is given.
S^
0
Assume
lies in the
A denote the set of left cosets of to each 2-simplex
E
of
K
cf
S,
jt^M-L)
S.
and ordered
there corresponds a generator of
On the other hand, to each generator of permutation of the cosets
(M, L).
jt^'M-L).
there corresponds a
determined by right multiplication
of a coset by that generator.
These twocorrespondences give rise to an
assignment of permutations of
A to the 2-simplices of
coboundary of each. a i-simplex in
M-L
of
S
^(M-L)
and hence leaves the cosets
fixed. Thus by Theorem 3.5.1
we may construct a covering from the
permutation assignment we have made.
Denote by
(M, )
t h i s covering.
l e t us use the same notation as before for the copies of
K,
that is,
Ma
of
S
which is S.
M
split along
a € A.
Take as base point in and located in
onto
and the ordered
is the identity because the product of the corres
ponding generators is the identity of Sg
K
The permutation induced by a small closed loop about
Mg S
(the copy of itself).
M
the unique point
M
split along
We need to prove
K
0
lying over
0
with index the coset
^(M, 0)
is mapped by
4>
§5.
Any closed curve, closed curve
21
CONSTRUCTION OP COVERINGS FROM A SPLITTING COMPLEX
c
based at
c,
0,
based at
0
is mapped by
&
into a
and furthermore, the permutation induced by
this latter curve (as in the construction preceeding the proof of Theorem 3.5.1, a curve in S
M
fixed since we find ourselves back in
tracing the curve S
induces a permutation of
c
over
c.
A)
must leave the coset
M g when starting there and
But if the permutation induced by S.
c leaves
fixed, then of course
c
represents an element of
Thus,
Conversely if
c
is a curve representing an element of
then the permutation it induces must of course leave the cosets of fixed, so that
c
may be lifted to a closed curvfe
c
based at
0.
S, S Thus,
This completes the proof of the theorem.
Before making an amusing application of this means of construct ing coverings we make the following observation which may be easily veri fied by the reader. If K is a 2 -complex in a 3 -manifold M, and M - K is connected, then an assignment of a permutation to each 2 -simplex of K and ordering of its coboundary, satisfying the condition that the product of permuta tions corresponding to the non-abelian coboundary of a i-simplex in K - L is the identity, may be used to construct a covering of M - L . In other words, if we weaken the conditions for a splitting complex so that M - K is not required to be simply connected and K is not required to contain L, we still may construct coverings of M - L from usable permutation assignments. The reason that all subgroups of
M - K jt^M-L)
was required to be simply connected was so could be used to construct coverings, if
however we are willing to accept something less than that, then
M - K
needn't be simply connected. Now, suppose a 2 -manifold, T, is imbedded semi-linearly in a 3-manifold
M
in such a way that
M - T
is connected.
Then assigning the
22.
III.
COMBINATORIAL COVERING SPACE THEORY FOR 3-MANIFOLDS
permutation (1 2 ) to each 2-simplex of a 2 -sheeted covering of i-simplex in
T
M
T
will permit the construction of
since (1 2 ) ~ 1 = (1 2 ),
and each coboundary of a
contains precisely two 2-simplices.
Thus we have proved
THEOREM 5.5.3. If a 2 -manifold can be semilinearly imbedded in a 3 -manifold, M, with out separating M, then M has a connected two-sheeted covering. COROLLARY 5.5.^. Any 2 -manifold semi-linearly imbedded in L(2 n+i, q) (lens space) separates. PROOF. 2,
so
L(2 n+ 1 , q)
« 1 (L(2 n+i, q)) « Z2 n+1
which 1:1813 no subgroups of index
has no connected two-sheeted cover.
As a final application of splitting complexes, an irregular covering of a knot is described by means of the picture below; there are three sheets and the permutations assigned to a 2 -simplex and its ordered coboundary "top to bottom” are as indicated.
These assignments determine
all the other assignments to 2 -simplices and their ordered coboundaries.
Fig. III-i*.
§5.
CONSTRUCTION OP COVERINGS PROM A SPLITTING COMPLEX
23
Before passing on to some applications of the ideas in this chapter, we may define A. group n1
The Monodromy Group
S C «1
of a covering corresponding to a sub
is the group of permutations of the cosets
S^
effected by right multiplication by elements of
representation of
«1
of
S
in
it is also the
as a group of permutations of the sheets determined
by mapping an element
g
mined by walking in M
n1
of
onto the permutation of thesheets deter
along a closed curve representing
g. * The equiva
lence of these two definitions follows from the proof of Theorem 5.5.1. B.
The Group of Covering Translations of a covering is the
group of permutations of the left -cosets of
S
induced by left multiplication by elements of of
S
Ma
which define a homeamorphlsm of
in
N(S).
in its normalizer, N(S)
N(S),
of these left cosets
It is also the group of those permutations of the sheets M.
Reiterating, the group of covering translations is on the one hand the normalizer of permutations of the
S
modulo
S,
and on the other the group of all
sheets which define homeomorphisms of
from the fact that a permutation of the sheets of phism of if
Mg
M
is mapped onto
Mgg
then
Mgw
is known> for where h
is mapped onto
is
for any
so that the permutation defining the home omorphi sm is induced by
left multiplication of the left cosets of
g's
plication of only when
Mg
is mapped onto
(M). This implies
multiplying any left coset of but these
defining a homeomor-
is completely determined when the image of
a generator of w €
M
M. This follows
are S
g € S,
S
S,
by elements
just the members of the normalizer of
by an element
g
g,
which when
on the left, give another left coset;
leaves the coset
S
S. Since multi
fixed when and
the equivalence of the two definitions of the group of
covering translations follows.
CHAPTER IV
THE COMMUTATOR SUBGROUP AND THE ALEXANDER MATRIX
§ i. Introduction
In this chapter we shall first study the covering of the comple ment of a knot corresponding to the commutator subgroup of its group.
This
will lead in a natural way to the Alexander matrix. Alexander's duality theorem implies that a knot group, modulo its commutator subgroup is infinite cyclic. III, the presentation for
G
G,
As remarked in Chapter
we have obtained has deficiency
+ 1 . This
state of affairs simplifies the study of the Alexander Matrix of
G.
We
shall discuss this matrix, as well as its elementary divisors, and it will be seen that the matrix determines group.
G
modulo its second commutator sub
The determinant of this matrix is the Alexander Polynomial and it
will also be examined.
We begin however, by proving a theorem which re
veals the structure of the commutator subgroup of a knot group.
Later in
the chapter, Crowell's work on the abelianized commutator subgroup will be described.
§2 . An Orientable Surface Spanned by a Knot Let
M
borhood + of a knot
denote the closure of the complement of a regular neigh k C si
Then
M
is a manifold with boundary, and by
Alexander Duality there exists an isomorphism
f
In the sense of [6 8 ], 25
3 = k.
k.
may be found in [5 7 ] and [1 8 ].
The Infinite Cyclic Covering of a Knot denote an orientable surface contained in
Suppose that the genus of
spanning of
S
k
k
is
g,
S
g
such that
arid that any other surface
has genus greater than or equal to
Obviously As
S
S3
g.
g is called the genus
is a knot type invariant.
isorientable we may orient each 2 -simplex
in
S
and
assign an ordering to the pair of 3 -simplices in each coboundary of a 2-simplex in
S,
so that the induced orientation cf the coboundary of
these simplices agrees with some pre-assigned orientation of
S3. If
a
§3.
THE INFINITE CYCLIC COVERING OF A KNOT
is a 2-simplex, denote this ordering the integers
(n-*n+l)
6(a).
to each pair
Now, assign the permutation of
(a, 6(a)),
then this assignment
defines, via the construction in Chapter III, a covering Any element
a 6 it^S3- k)
27
M
of
S3- k.
having linking number (58)
o
with
k belongs to the subgroup of this covering, for it will have intersection number [58]
o
with
S,
and this implies that the permutation of the in
tegers (sheets) induced by
ct is trivial.
Conversely, if a
the subgroup of this covering, it follows that o
with
k.
belongs to
must have linking number
Thus we have constructed the covering of
to the commutator subgroup of
a
S3- k
Corresponding
^ ( S 3-^.
Particularizing the description in Chapter III, we obtain by taking a countable number of disjoint copies of indexed by the integers, and pasting copy "right hand" copy of S
in copy
S, iS1
in
S3
xi-, i-is i
X = (S3 split along S),
to copy
Xi+1
along the
X^^ and the "left hand" copy
X^+1. The common copy of Copies of
Xi
k
in each
split along
M
X^
i+1S2,
of
is then removed.
S
X i+1
xi iS2
iS, i+1S2
We shall use the notation of the above picture in the next section. The group of covering translations of since the commutator subgroup is normal.
M
is infinite cyclic
The group of covering translations
may be generated by the permutation of the sheets sending X^ Denote the covering translation sending
§U.
to
Xi+1«
by tn .
A Property of the Surface of Minimal Genus
(S3 split along which we denote
X^
to
S) = X
has on its boundary two copies of
S1, S2, noting that
S1
U S2 = dX,
S1 n S2 = k.
S,
28
IV.
THE -COMMUTATOR SUBGROUP AND THE ALEXANDER MATRIX I£MMA !♦..!»..i. The inclusion map induces a monomorphism hf:
PROOF.
Since
zero, hence no power of homotopic.
k
is knotted,
k
S1 dX -* ^(dX).
is of genus greater than
considered as an element of
dX = S 1 U Sg, and
Since
S^
h:
S 1 n Sg = k,
^(S^)
is null
a simple application
of the van Kampen Theorem gives
*.(dX) * * (S.)
1 jc1 (S1)
Thus,
*
*,(SJ
1 1 *,(k) 1 2
is imbedded monomorphically in
by the inclusion
n^dX)
by a map induced
h.
LEMMA k . k . 2 . The inclusion map v: S. -♦ X JL 1 induces a monomorphism vT : (S1) -► n 1 (X) . PROOF. curve on
S1,
Lemma if.U.i.
Suppose the lemma is false, and that
such that a £ o
polygonal so that
on
X
or s o dX.
and
in X,
Since S 1
a £ o
on
a
is a closed
S 1.t According to
is polyhedral,
a
may be assumed
oc satisfy the hypothesis of the LoopTheorem
([5 0 ], Theorem 1 5 . 1 and Theorem
1 ), thus we may assume that
According to Dehn's Lemma [5 1 ],at
bounds a
in
X.If we cut
S1
along a, and sew discs to both sides ofthe
obtain a new surface rates
S1,
of
than
S.J, of
£
0
on
S1,
at
does not separate
S1, X(S1), with that of
one edge, and two faces,
curve
at
the
k.
If the curve
new surface
Sj
S1,
x(S’) - x(S.,) * 2 ,
sepa
has lower S1
then compare the Euler Charac
hence
so we again arrive at a contradiction.
S^
has lower genus
The existence of the
thus leads to a contradiction, so the lemma is proved.
denotes homotopic to."
cut we
Sj. Since the cut adds one vertex
REMARK. Lemmas 1 and 2 obviously remain valid if S2 is substituted for S1. Lemma 2 also remains valid if k is removed from X. s
at
S1, which contradicts the assumption that the genus of
is minimal. If teristic
S ’ which is bounded by
then because
genus than
is simple
at
non-singular polyhedral disc
§5.
THE STRUCTURE OP THE COMMUTATOR SUBGROUP OP A KNOT GROUP
29
Roughly speaking, what this lemma means is that non-contractible curves on a surface in
S3- S
S,
of minimal genus spanning
k
are non-contractible
if they are pushed off the surface (to either side).
§ 5 . The Structure of the Commutator Subgroup of a Knot Group. For the rest of this chapter
G will denote
i^CS - k).
THEOREM 4 .5 .1 . If CG, G) is finitely gen erated, it is free of rank 2g, where g is the genus of k. If [G, G] is not finitely generated, then either it is: A) a non-trivial free product with amal gamation on a free group of rank 2g, and may be written in the form
P
* A * A * A * A * A ••• PP P P P 2g 2g 2g *2g 2g *2g
,
where F2g Is free of rank 2g, and the amalgamations are all proper and identical, or B) locally free, and a direct limit of free groups of rank 2g.
REMARK. PROOF. identification of every
I do not know if case B) can occur.*
By virtue of Lemma 4.2, the last remark in §4 and the iS1
and
i+1S2,
i,
f i1! where
the following diagram is valid for
the
f i+1 2
are mon o m o r p h i s m s .
R. Crowell has informed me that E. Brown and he have proved that case B) cannot occur.
30
IV.
THE C0MUTAT0R SUBGROUP AND THE ALEXANDER MATRIX
By a simple application of the van Kampen Theorem, the funda mental group of
U
X^
is the direct limit of the above system.
This
* 1 (Xi) * *i(Xi+i)-
direct limit is a free product with amalgamated subgroup, Let
*i(is i>
In -Xo UX, U ••• V i
U*n.
n>0
T.n -X., U X . a U ••• X^, U X _ n, 00
Y
=
n>l
00
U x. i=i
=
Y
1
U
"
X,
i»-i
1
.
Using the fact that each factor in a free product with amalgam ation is contained as a subgroup in the free product with amalgamation [3 3 ] and proceeding inductively it is clear that frcm the above diagram one obtains, (I)
., 0 isomorphism of
-
([33], p. 3 2 ).
§5.
31
THE STRUCTURE OP THE COMMUTATOR SUBGROUP OP A KNOT GROUP It follows then that
^(Yj
C xJYJ,
« 1 (Y_1) C ^ ( Y ^ J .
and
This fact and the diagram above imply that
* ,0 0 = * ,o r _ . U Y J = « ,( Y .J Note that if
k is of genus
g, then
1=1.
Then no
jf^
« ,( T J ^(S)
.
is free of rank
x J q S J -► « 1 (XQ)
Suppose one of the maps, say for
.
2 g.
is not onto,
will be onto, so that
U Y J c «,(y_ 8 U y J
*,0rj c «,(y_,
•••
and
*,(X) so that is onto
xJX)
«t(S)
* ^(XJ
then all
- ^(YJ
* V Y -n U YJ
and
« 1 (X)
is free of rank Qf 1
generated,
«,(Y.n U Y j *1 (0 S1) -*■ *.(X0)
is not finitely generated. But if
i = i, 2 ,
for
U
n= 1
and
Qf2
jf^
are onto so that
** x j Y j - ^ ( Y J ~
^ *i(Y-oo U YJ
2 g.
Hence if
are onto and
(Y_ 1 U Y J
- *i(X>
[G, G] = x^X)
x^X)
is finitely
is free of rank
2 g.
This
proves the first assertion of Theorem 4A.1.
If neither of the mappings jt.(Y 1
) * x,(S)
x (Y ) 1
is a proper free
),
free product with amalgamation of 2g
is proven.
is onto, then
wjX) =
productwith amalgamation and may
00
be written as ii5L> x (Y U Y n > o 11
of rank
Q? 1
isomorphic to
where each
^(YJ
xJS),
Suppose one of the maps,
so
x (Y U Y ) > n -n
and
is aproper
on a free S1*011?
by virtue of equations i and 2 , A) Qf^,
is onto,
say
Qf2, and the
32
IV.
other,
THE COMMUTATOR SUBGROUP AND THE ALEXANDER MATRIX
is not, then % *i o 00
U Y _)
• Since the
mappings in this direct system are allinclusions, it follows finitely generated subgroup H
H C ^(X)
that any
lies in some ^(Y^ U Y_n) and so
is a subgroup of a free group and hence free [U7]; in other words,
jt^X) = [G, G]
is locally free, and
proof of the theorem.*
B)
is proven.
This completes the
This theorem has many implications which will be
found scattered throughout the remainder of the book.
We state one corol
lary here which will be used in this chapter. COROLLARY U.5 .1 . The center of trivial. PROOF. > 1
If
[G, G]
[G, G]
is
is- finitely generated, it is free of rank
according to Theorem ^.5 .1 , hence If
[G, G]
is not finitely
the corollaryfollows. generated, itis either a free
product with amalgamation on a centerless group and hence centerless according to [3 3 ] p. 3 2 , or else locally free and non-abelian and hence centerless. Q.E.D. * The homeomorphism may be taken to be the covering translation restricted to Y -n _ U Y °°. * The proof given above is identical to that given in [^U].
tn
§5.
THE STRUCTURE OP THE COMMUTATOR SUBGROUP OP A KNOT GROUP Whether cr net
upon
G*
33
is finitely generated we may still look
G ? as in the picture below
A generator, acts upon
t,
G ! by mapping
duced by the action of Thus
G
t
t
A^
upon
G/G1 of covering translations
1 by the natural isomorphism in
on
may be described by giving the structure of
indicated in Theorem 4.5.1, jugation by
of the group
since the automorphism of
coincides with the action of
t
on
G*
as
G 1 induced by con
G T induced by a
covering translation. It is appropriate to mention here two results of Crowell [9 ] and Rapaport C53 3, and a result of Murasugi [4ol.
First, a theorem which
will be proved in § 9 of this chapter: THEOREM 4 .5 .2 . (Rapaport-Crowell) If G ’ is finitely generated, then |Aq(o)| = 1 . Here
A^(t)
is the Alexander polynomial, an invariant to be
described in §7. Secondly, a partial converse to Theorem 4.4.1, THEOREM 4.5.3. (Rapaport-Crowell) If is free it is finitely generated.
G1
Finally a theorem giving sufficient conditions for finitely generated. THEOREM 4 .5 .4 . (Murasugi) If k is alternating and |a(o)| = 1 , then G* is finitely generated.
G*
to be
IV. §6.
THE COMMUTATOR SUBGROUP AND THE ALEXANDER MATRIX
The Alexander Matrix (Tentative Description)
In a paper [2] published in 1933, J. W. Alexander constructed over a certain ring, a matrix whose determinant, he proved, was up to a unit an invariant of the knot type of
k.
Since that paper, the matrix
he constructed has been constructed by several other people by several different methods [20], (57], [M ]. We shall give an interpretation of the Alexander matrix in this section, but the proof will be postponed. Recalling Chapter II, 1 - G'/G" - G /G" - G/G’ a module over
o
A)
|t: |, on
G'/G".
G'/G", since
G/G’ is free, thus
G/G’. It is clear that the structure of
with the module structure of
® G'/G"
G/G* = |t: | acts on
isexact and
G/G"
is
is tied up
We now assume:
The Alexander Matrix of
k
is a presentation
[9 ] of
considered as a module over the integral group ring of where
G'/G"
G/G’ acts by multiplication on
G/G'
G/G"
G/G’ =
and by conjugation
G ’/G”. It will also be convenient to assume the following easily proved
fact. B)
Suppose
G, H
areknot groups, then
G ’/G"
isomorphic as modules over the integral group ring of respectively if and only if
G/G"
and
H/H"
and
G/G'
H'/H11
are isomorphic.
We remark finally that the Alexander Matrix of a knot group may be computed from a finite presentation of
§7. If then the ideal, of
G.+
A
is an a,
are
and H/H'
G
G,
[2 0 ].
The Alexander Polynomials n columned Alexander Matrix for a knot group
generated by the minors of rank
n-d
G,
is an invariant
A generator of the smallest principal ideal containing
a
is
* It is proved in Zassenhaus, Theory of Groups, that given a matrix, these ideals are invariants of a module which the matrix may be assumed to present, and we have assumed that the Alexander Matrix, in fact, presents a module which is an invariant of the knot group. Accepting these facts makes most of this section academic.
§7. called the
THE ALEXANDER POLYNOMIALS
dth Alexander Polynomial of
unit, of course.
G;
35
it is determined only up to a
The invariance of these polynomials is not obvious, nor
is it trivial to prove.
One proof depends upon the Tietze Theorem on
equivalence of presentations of isomorphic groups [2 0 ].
To understand this
proof one should appreciate the manner in which the Alexander Matrix may be constructed from a finite presentation of a group.
We do not wish to de
velop the free calculus here, so that we must refer the reader to [2 0 ] and [1 9 ] for a full account of the construction of the Alexander Matrix.
The
proof goes roughly as follows: 1 . Denote by
G, H
two knot groups, by
the infinite cyclic group generated by 2.
Suppose
3.
There must exist
G
and H
the group ring of
t.
are isomorphic. a finitesequence of Tietze transformations
[61] from a finite presentation of k.
JZ
G
to a finite presentation of
H.
Tietze transformation I adjoins a new relation which is a
consequence of the old relations.
The effect on the Alexander Matrix of
such an operation is to adjoin a new row which is a linear combination of old rows with coefficients units in
JZ.
This operation and its inverse
leave invariant the ideal generated by the minors of rank 5.
n-d.
Tietze transformation II adjoins a new generator and a new
relation setting this generator equal to some word in the old generators. The effect on the Alexander Matrix is to adjoin a new row, and a new column of zeros, except for the entry common to the new row and column, which will be a
1 . Obviously, the ideal generated by the minors of rank
n-d
of
such a matrix is unaffected by such an operation, or its inverse. 6. of
G
Numbers 3,
are an invariant of
and 5, imply that the Alexander Polynomials G.
36
IV.
THE COMMUTATOR SUBGROUP AND THE ALEXANDER MATRIX
We shall subsequently indicate heuristically, how the Alexander Matrix is a presentation [9 ] of
G'/Cr"
as a module over
G/G1. If as
agreed earlier we assume this last statement, an alternative proof of the invariance of the Alexander Polynomials may be given along the following lines.
We use the same notation as the previously outlined proof.* 1 . G'/Gr" = M
over thegroup
ring of
2 . If
of
M and
A
and
H f/H" = N
must be isomorphic as modules
G/Gf«* H/H1 which we denote
and
B
N respectively,
JZ.
are presentation matrices (Alexander Matrices) then the matrix, C,
below presents M
or
N.
A, B have at least as many rows as columns. (Rows of zeros must be added if necessary.) A O
I
P
I
0
B
0 C =
I Q
is the identity matrix of the appropriate size. is a matrix of zeroes of the appropriate size.
P
Q
describes the generators of the presentation of N in terms of the generators of M. describes the generators of a presentation of M in terms of the generators of N.
0
B
1
Q
3. Each row in the matrix A
0
P
I
the rows of
,
is a linear combination of
, and conversely.
Number 3 implies that the ideal generated by the minors of C of rank
n - d
is equal to the ideal generated by the minors of rank
O B n - d
of
A O or
I Q
P I
§7.
THE ALEXANDER POLYNOMIALS
ideal generated by minors of rank r + s - d of
So that
r 0
s B
1
Q
ideal generated by minors of rank u - d of
and
A
37
ideal generated by minors of rank u + v - d of ideal generated by minors of rank s - d of
=
U
V
A
0
P
I
B,
and this implies the desired result.+ If
A
denotes a square matrix presenting
G'/G",
then we
contend: PROPOSITION k .7.1. Det A every element of G'/G". PROOF. matrix
A
F/ im A
[9 ].
Denoteby x € F,
q> the natural map from
then
det A
so that
F to
xA is in the kernel of
= (adj A)A = (det A)I, we see that
x(adj A)A = yA, that
With the same notation as before, we may consider the
as defining an endomorphism of a free module
If A(adj A)
annihilates
,
which' implies
M.
In a moment a much more general theorem of Crowell will be proved. We shall postpone until § 9 some theorems about the first Alex ander Polynomial.
In the next section we return again to consideration of
the Alexander Matrix.
At this point we present some of the high points of
Crowell's investigations [93, [1 0 ], into the module structure of
G'/G".
The proofs we give are Crowell's. We begin by fixing notation. ring of ideal in
G ’/G".
A
denotes the
Jt' which annihilates
Jt
Jt module A.
denotes the integral group G ’/G".
, f/ Q « ^ % «p '0 (0 2' 1'0 1 =
1
so
\|r(t)
d
so that
q>(xi)
must equal *(t) = t.
d q>“1(xi)d~1= y ( X ] )
modulo ^(t)
If
freely generate i.
G ’ and
On the other hand,
♦
is non-trivial on
9 (d)xi«p(d”1) = cp2(xi)
M G”
2g,
G 1 is free of
d - F) c A,
then
(P, cppi) € A.
There is a dis
and there is at least one
A
to
78 Ax. i*-.
VIII. If
(F, H)
* q>p(G) *
We remark thatas
are in
A,
H, q O
then is in
F and
H
q>F
or
q>g,
.
are canonically subgroups of the
free product with amalgamation, the placement of defined by either
A
p ) o (H, q>H) . Define a binary relation,
r,
between elements in
A
(F, (pF )r(H, q>H),if and only
if
¥( (F, q>p) o (H, cpH t))
as
follows:
admits an involution which induces CLAIM: PROOF.
r
i on the subgroup
Is symmetric.
Consider
F
*
t(g') = g,
H = L, and
0.
Take
G
to be the two point space
(m = n * 0),
t
to be the
interchange of these two points, and as imbeddings the maps putting these points (in either order) at the place indicated by the arrows in the above figure.
It can be seen that two whiskers
(P, q>F),
(H, F )
onto the integer (number of whiskers emanating from the image of 1) minus (number of whiskers emanating from the image of 2). Another topological adaptation of the construction is to take for the operation
o,
the cartesian product of spaces with base points, with
one subspace identified with another. and ((Y, yQ), qpy) (G, ga)
More precisely, if
are two spaces with basepoints and
((X, xQ), cp^
q>x ,
in each, then define
((X, x0), ¥x) o ((Y, y0->, * ) = ((Z, z0), (jj
where
imbed a space
$5.
SOME EXAMPLES
83
Z . X x Y/(p) r (F,
ip)
This may beproved as follows:
y ((F,
q>p) o (F, ip O ) = L
y ((F,
q>p) o (F,
is isomorphic to
by a mapping, say
p.
A meridian
m'
u
u
n (k ,, ... Kgn ; I l t K g ^ , i-1
n (H,, ... H2n: II 1 % . , , ^ l ) i=1
u
u (H g ,
...
H2 n :)
.
(K g ,
...,
Kgn )
W l ~ Yi
p:
= *n
morphism of the free group
for
G ’?
that there exist knots for which automorphism.
G*
n > 1
and
t
cp of
an auto
Giffen proved in his thesis q> = *n
modulo an inner
(This is related to the Smith conjecture
(Chapter III) as it applies to knots with
G* finitely
generated.) K.
Can Case B) of Theorem U.5.1 actually occur?*
L.
Is the decomposition in Case A) of Theorem U.5.1unique the sense that the rank of the amalgamating subgroup is always twice the genus?
See the first footnote to Chapter IV 55.
in
§2. M.
PROBIEMS
101
Does there exist a knot group with a non-trivial symmetry leaving a peripheral subgroup (Chapter VII) element-wise fixed?
(This is sort of an algebraic version of the Smith
problem.) N.
Can a knot group be ordered? G1
with
(This is easy for knot groups
free.)
0.
What can be said of the Frattini subgroup of a knot group?
P.
Is there a simple condition on an automorphism free group
F,
of rank
is left fixed by erators of
F.
of a g ni = 1 [ai,b13
are a set of free gen
The interest in this question of course,
stems from the hypothesis of Theorem 9 .2 .3 . Q.
Does the commutator subgroup of every knot group have cohomological dimension 1 ?
(This would provide an example of
a group with geometric dimension 2 , category 2 , and cohomo logy dimension 1 . Perhaps in any case a perfect commutator subgroup (see Chapter IV) of a knot group is an example of such a group). R.
Does there exist a useful algebraic theory suggested by the Morse theory in dimension three?
This might involve a gen
eralization of Stallings* theorem (59). S.
Can a knot group contain an element equation of
T.
xn = g
g ^ 1
such that the
has solutions for arbitrarily large values
n?
Every knot group contains the group
(a, b; [a, b)).
This
subgroup may be obtained from zhe natural inclusion of the fundamental group of a non-singular torus in the knot group. Suppose a knot contains the group of a closed surface of genus
g.
of genus
Does there exist a non-singular colsed surface g
whose fundamental group is injected monomorphic
102
XI.
PROBLEMS
ally Into the knot group by the natural Inclusion? U.
Suppose
H
is a group satisfying
a) H/H* - ZR ; b) H
may be finitely presented with atleast
asmany
relations as generators. Is V.
H a
hctncmorph of a knot group
An arbitrary knot group
G ?
G must contain
a) A free group of any rank; b) A free abelian group of rank 2. Must
G
contain any other groups?
(By Theorem U.5 .1 , G W.
contains a free group
of rank 2 .)
Can the word problem be solved in a knot group? (Perhaps this follows from Theorem U.5 . 1 or a positive solution to Problem B.)
X. Y.
Can one decide algebraically if a knotgroup
is cyclic?
Can one select geometrically significantrepresentatives from each conjugacy class in a knot group?
Z.
Can the crookedness of a knot type [U9 ] be algebraically determined?
APPENDIX by S. Eileriberg
Let
A
be a category (which for the sake of simplicity will
be assumed to be small, i.e., the objects of set).
Let
6 . [21*]
H. Gluck, The Reducibility of Imbedding Problems, The Topology of 3-Manifolds and Related Topics. Prentice-Hall,1 9 6 1 .
[2 5 ] H. Freudenthal, Ueber die Enden topologischer Raume und Gruppen, Math. Zeit., 31 0931), pp. 692 -7l3. [26]
C. H. Giffen, Princeton Ph.D. Thesis, 1 9 6 ^.
[2 7 ] A. Haefliger, Knotted Ok - i )-Spheres in 6 k-Space, Ann. of Math., vol. 75, no. 3 (1 9 6 2 ). [28]
M. Hirsch and L. Neuwirth, On Piecewise Regular n-Knots, Ann. of Math. (to appear).
[2 9 ] H. Hopf, Enden offener Raume und unendliche dlskontinuierliche Gruppen, Comment. Math. Helv., _i_6 09^*0, pp. 8 1 - 1 0 0 . [30]
K. Iwasawa, Einige Satze Uber freie Gruppen, Proc. Japan Acad., V9
[31]
S. Kinoshita, Alexander polynomials as Isotopy
09**3), pp. 2 7 2 -271 *.
Math. J., n_ (1959), pp. 91-9^.
Invariants II, Osaka
REFERENCES [32]
109
S. Kinoshita, On the Alexander Polynomial of 2-Spheres in a l*-Sphere, Ann of Math., vol. 7**, no. 3 (1 9 6 1 ), pp. 518-531.
[33]
K. A. Kiirosh, The Theory of Groups, vol. I, II, Chelsea, New York, 1955.
[31*3 W. B. R. Lickerish, A Representation of Orientable Combinatorial 3-Manifolds, Ann. of Math., vol. 76 no. 3 (1962). [35] R. Lyndon, Cohomology Theory of Groups with a SingleDefiningRela tion, Ann. of Math.,
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Ui]
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[1*3]
D. R. McMillan Jr., Homeomorphisms on a Solid Torus, Proc. A.M.S., vol. Jj*, no. 3 (1963), pp. 386-390.
ChU]
L. Neuwirth, Interpolating Manifolds for Knots in
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[1*5]
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INDEX Imbedding Theorem, 22
Abhyankar's Question, 61, 63 Alexander Matrix, 3h ff.; Polynomials, 3k, k6 , 86 algebraic symmetry, 73 algorithm, 87 amalgamation, free product with, 5 Annihilator Theorem, ho
longitude, 68 meridian, 68 Monodr any Group, 23 path lifting, 1 7 periodicity theorem, 53 presentation, 2, 5 Dehn, 1 h Wirtinger 1 5
cave, 9 , 10 center, 3 2 , U6 , 57, 58 coboundary, 7 ; non-abelian, 1 1 , 1 6 , 17 commutator subgroup, 2 9 , 3 3 , k7 covering, combinatorial 9 ff. covering translations, group of, 23
Smith Problem, k9 spanning surface, 2 5 - 2 5 splitting complex, 1 2 , 1.3 Structure Theorem (for G f), 29 surface, spanning, 2 5 - 2 6 symmetry, algebraic, 73
deficiency, 5 , 1 5 Duality Theorem, 91 genus, 26 Goldstein, Peter Strom, 3 group system, 67, 9k, 97
whisker space, 82
113