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English Pages 498 [496] Year 2016
Annals of Mathematics Studies Number 115
ON KNO TS BY
LOUIS H. KAUFFMAN
PRINCETON UNIVERSITY PRESS
PRINCETON, NEW JERSEY
1987
Copyright © 1987 by Princeton University Press ALL RIGHTS RESERVED
The Annals of M athem atics Studies are edited by W illiam Browder, Robert P. Langlands, John M ilnor, and Elias M. Stein Corresponding editors: Stefan H ildebrandt, H. Blaine Lawson, Louis Nirenberg, and David Vogan
Clothbound editions of Princeton University Press books are printed on acid-free paper, and binding m aterials are chosen for strength and durability. Pa perbacks, while satisfactory for personal collections, are not usually suitable for library rebinding.
ISBN 0-691-08434-3 (cloth) ISBN 0-691-08435-1 (paper)
Printed in the United States of America by Princeton University Press, 41 W illiam Street Princeton, New Jersey
☆
Library of Congress Cataloging in Publication data will be found on the last printed page of this book
To
the M e m o r y A ndres
Re y e s
of
CONTENTS
P R E F A C E .....................................................ix I.
I N T R O D U C T I O N .............................................
3
II.
L I N K I N G N U M B E R S A N D R E I D E M E I S T E R M O V E S .............
9
III. IV. V. VI.
THE C O NW A Y
E X A M P L E S A N D S K E I N T H E O R Y ............................... 42 D E T E C T I N G S L I C E S A N D R I BB O NS ,
13. 14. 15. 16. 17. 18. 19. 20.
VIII.
AF I R S T
PASS.
70
Q u a t e r n i o n s a n d B el t T r i c k ....................... 93 R o p e T r i c k ........................................... 98 T o p o l o g i c a l S c r i p t .............................. 100 C a l c u l i ............................................... 103 I n f i n i t e F o r m s ..................................... 106 Q u a n d l e s .................... 110 T o p o l o g y of D N A ..................................... 113 K n o t s Ar e D e c o r a t e d F i b o n a c c i T r e e s ............ 115 A l h a m b r a M o s a i c ..................................... 1 2 0 O d d K n o t ............................................ 121 P i l a r ' s F a m i l y T r e e ................................ 122 Th e U n t w i s t e d D o u b l e of the D o u b l e of the F i g u r e E i g h t K n o t ............................. 123 A p p l i e d S c r i p t — A R i b b o n S u r f a c e ............. 124 K i r k h o f f ’s M a t r i x T r e e T h e o r e m .. ............... 129 S t a t e s a n d T r a i l s ...................................132 T he Ma p T h e o r e m .....................................147 The M o b i u s B a n d .....................................152 Th e G e n e r a l i z e d P o l y n o m i a l .................... 155 T h e G e n e r a l i z e d P o l y n o m i a l an d R e g u l a r I s o t o p y .............................................. 163 T w i s t e d B a n d s ........................................179
SPANNING SURFACES AND SEIFERTPAIRING
..............
181
R I B B O N S A N D S L I C E S ....................................... 208
IX.
ALEXANDER
P OLY N OM I AL AND B R A NC H EDC O VE R I N G S
X.
ALEXANDER
P O L Y N O M I A L A N D AR F
XI.
. . .
M I S C E L L A N Y ...................................................92 1. 2. 3. 4. 5. 6. 7. 8. 9. 10. 11. 12.
VII.
P O L Y N O M I A L .................................... 19
.
. . 229
I N V A R I A N T ...............252
F R E E D I F F E R E N T I A L C A L C U L U S ..............................262
vi i
XI1 .
. . . . . . . . . . . .
271
. . . . . . . . . . . . . . .
299
. . . . .
327
CYCLIC BRANCHED COVERINGS
XI11 . XIV . XV . XVI . XVII . XVIII . XIX .
SIGNATURE THEOREMS
G-SIGNATURE THEOREM FOR FOUR-MANIFOLDS
SIGNATURE OF CYCLIC BRANCHED COVERINGS . . . . . 332 SLICEKNOTS .
337
. . . . . . . . . . . . . . . . . .
345
CALCULATING or FOR GENERALIZED STEVEDORE'S . . . KNOTS . . . . . . . . . . . . . . . . . . . . . . 355
. .
366
. . . .
417
. . . . . . .
444
SINGULARITIES. KNOTS AND BRIESKORN VARIETIES
APPENDIX: TABLES:
. . . . . . . . . . .
AN INVARIANT FOR COVERINGS
Generalized Polynomials and a States Model for the Jones Polynomial . . . .
Knot Tables and the
REFERENCES
L-Polynomial
. . . . . . . . . . . . . . . . . . . . . . .
474
PREFACE
These notes panded
version
on
the
th e or y
of a s e mi n a r
G e o m e t r i a y T o p o l o g i a at Z a r a go z a,
Spain during
of k n o t s
held
in
the U n i v e r s i d a d
the w i n t e r
of
the
this a u t h o r
(we b e l i e v e ! )
careful
Du e
of
and
to
the
the m e m b e r s
the e n e r g y
set of notes,
de
de Z a r a go z a,
1984.
e n t h u s i a s m a nd p e r s i s t e n c e was g i v e n
ex
the D e p a r t m e n t o
supernatural seminar,
c o m p r i s e an
of
to r e c o r d a
to r e l i s h
the
process. The n o t e s d i a g r a m moves,
begin with an d
( pe r h a p s
steep ly ) ,
problems
of k n o t
the mo s t
elementary
li n k i n g numb er s . using minimal
c o b o r d i s m an d
Then
they m o v e
t e c h n ic a l
the Arf
concepts
quickly
apparatus,
invariant
of
to
(Chapters
1 t h r o u g h 5). Chapter
6 is a m i s c e l l a n y ,
course.
It c o n t a i n s
ideas,
The
sections
this
last
the a u t h o r ' s polynomial
of
geometric
( [ HO MFLY],
This polynomial izes
the c l a s s i c a l
s how h o w i sotopy
compiled
si d et r ip s ,
chapter
musings [J01],
on
the
[J02],
new polynomial
of k n otted,
can be u s e d
s p e c ia l
topics. of
first g e n e r a l i z e d
[J03]). invariant
that g e n e r a l
an d C o n w a y p o l y n o m i a l s .
the g e n e r a l i z e d p o l y n o m i a l invariant
an d
the
c o n t a i n an e x p o s i t i o n
is a p o w e r f u l
Alexander
throughout
a rises
We
as an a m b i e n t
t w i s t e d bands,
an d h o w
to d i s t i n g u i s h m a n y k n o t s
the from
X
PREFACE
their
m irror
images.
Chapters geometric covering
7
kn o t
through
18
then d e v e l o p m o r e
t heo ry— w ith co ver ing
spaces.
(combinatorially)
polynomial
and
k no t
to s k e i n
t h eo r y b e g i n s
spanning
surfaces
S-equivalence S-equivalent
Seifert ^0')
7.
It
to p r o v e
that
the k n o t
ends
w i t h a ke y
identity
(v^
exe r ci s e, is
on
to s ho w
image by
points
to
asking
We d i s c u s s
isotopic knots the p o t e n t i a l
the S e i f e r t
have function
signature
the
The
in C h a p t e r
changes
image.
r e a de r
for
p a i r in g .
introduced
its m i r r o r
i aK (A -1) .
Th i s
is
* s not: a m P h i c h e i ral .
^42
that
mirror
to
the
i n t r o d u c t i o n of
sign
Chapter
to p r o v e
7
the
the C o n w a y p o l y n o m i a l )
^42
the k n o t
of
into g e o m e t r i c
p r o d u c i n g a m od e l
is a ls o
is r e p l a c e d by
—— i v^(2>l-1 )/| Vj^(2>l-1) | = that
terms K
when
Then
i n tr o du c ed , in
the
p a ir i ng .
that a m b i e n t
of a k n o t
is ea s y
7 with
p a i ri n gs . is
(Alexander)
The a s c e n t
the S e i f e r t
the C o n w a y p o l y n o m i a l signature
the C o n w a y
theory.
and prove
= Det(t0-t
to
in C h a p t e r and
s pa c es a n d b r a n c h e d
6 the r e a de r has a l r e a d y b e e n
By C h a p t e r
introduced
te c h n i c a l
c an n o t
then u s e d The
the o p e n q u e s t i o n
the p o s s i b i l i t i e s
exercise
be d i s t i n g u i s h e d
the g e n e r a l i z e d p o l y n o m i a l . of
i n he r e n t
to show
fro m This
g oe s
its exercise
s e t t l i n g a m p h i c h e i r a l i t y and in n e w
i nvariants
s u ch as
the
generalized polynomial. Chapter
8 returns
relationship with
to kn o t
the S e i f e r t
c o b o r d i s m an d d i s c u s s e s p a i r i n g an d w i t h
surgery
the
xi
PREFACE
curves
on
the
Alexander infinite cuss
spanning
polynomial cyclic
Seifert's
cyclic
terms
covering
one
is a b ri e f
introduction
complement.
We
its
relation
of
groups.
is a n o t h e r
into a c l a s s i c a l
a nd
on h y p e r b o l i c
the w o r k
complements
of R i l e y
(via r e p r e s e n t a t i o n s
i n d i c a t e a d i r e c t i o n here. the
link b e t w e e n
t acular
results
Chapter and
shows
how
tion p a i r i n g
12
these n o t e s
to c o m p u t e
explanation
S ei fert
p a i r i n g a nd b r a n c h e d of
a key
both
for
the
st u dy
entrance
into
signature the
for
exe r ci s e, by D e R a h m , on kn o t We
o nly
exercise
w ork and
T hi s the
coveri n g.
signatures
of
of
repre
the
is
spec
school.
on a s s o c i a t e d m an i f o l d s .
with a computation
this
their h o m o l o g y v i a
(more m o d e r n )
affine
key
11
calculus
g r o up s ).
cyclic branched
another
example
an d R i l e y ' s
of T h u r s t o n an d his introduces
Chapter
paper
Nevertheless,
in
Theorem
structures
of kn o t
of
the A l e x a n d e r
eight).
p r o vi d in g an entry point to
dis
invariant
free d i f f e r e n t i a l
T his
the
the
Levine's
It ends w i t h an e x e r c i s e a b o u t
of kn o t
to
the Arf
the v a l u e
the
to
computing homology
(ta ke n m o d u l o to
the
and
an d p r o v e s
to
9 relates s pa c es
10 d i s c u s s e s
invariant
at m i n u s
for
an d
pai r in g ,
polynomial
sentations
the kn o t
method
Chapter
the Arf
of R a l p h Fox.
of
c o v er i ng s ,
the S e i f e r t
relating
to b r a n c h e d
original
p a ir i ng .
of
Chapter
covering
(b r an c h e d )
Seifert
surfaces.
coverings the
intersec
leads
to
relationship The
chapter
torus knots.
c omputations,
topology
again,
an d
of
ends T h is
is
for an
of a l g e b r a i c
xii
PREFACE
singularities
( w h i c h we d i s c u s s
Chapter
introduce
12 we
m a n i f o l d an d knots
and
covering of
sh o w h o w
links are sp a c e s
the
of
signatures
in fact
19).
the
an d
signatures
Within
signature
of a
w-signatures
of b r a n c h e d
eigenspaces
in
of
cyclic the case
(J-s i g n a t u r e s ) .
giving
the
13 we p r o v e
signature
the p ieces.
manifolds that ants. on
the c o n c e p t
(or of a p p r o p r i a t e
In C h a p t e r
of
in C h a p t e r
signatures
to d i s c u s s
s ur f aces, basic
(case
signature
an d a n a r g u m e n t
gives this
of
of
skew
then a s s e m b l e
In C h a p t e r
the
a nd
the p r o d u c t
the case
defects
two m a n i f o l d s
that
signatures
these g e n e r a l
g-signatures
in
and
a nd use
of k n o t s
We p r o v e
g-signatures
of a u n i o n of
We a l s o p r o v e
va n is h ,
eigenspaces
the N o v i k o v A d d i t i o n T h e o r em ,
for
14 we b u i l d
links are theorem
for
these
to show
concordance
of
invari
si g n a t u r e s , signatures
c y c l i c a c t i on s . forms)
of b o u n d i n g
results
for
in terms
in terms
We
cyclic
results
a n d go of
compute
actions
to o b t a i n
on the
four-manifolds. on
the
of C a m e r o n G o r d o n
results
of C h a p t e r
to g i v e a p r o o f - s k e t c h
G-signature
theorem
for 4 - m a n i f o l d s .
a complete
picture
of
through
18 are an e x p o s i t i o n
the
13
Th i s
G-signature
of
exposition
theorem
in
dimension. Chapters
15
of C a s s o n an d G o r d o n the p r e v i o u s covering
work,
spa c es
and
on
slice knots.
particularly upon G-signature
T hi s the
theorem.
of
the w o r k
depends
u p o n all
cyclic branched
xi i i
PREFACE
In C h a p t e r
19 we g i v e a n
of a l g e b r a i c
singularities
of k n o t s
links.
their
an d
specific space,
discussions
and
the M i l n o r
ideas.)
With
results
intimately
example
of
In p a r t i c u l a r ,
related
(large
generalized is g i v e n
relation
to
We
s p h er e s
conclude
of
the a u t h o r ' s
M u r a s u g i , and mo d el
to
the J ones
find to see
branched
chapter
in the
list
cov
w i t h an
twos). further
developments a descrip
polynomial
the J on e s
polynomial).
and
polynomial.
that
the author,
to M o r w e n T h i s t 1e t h w a i t e — all for
covers
con
via Bri eskorn m a n i
to a l t e r n a t i n g k n o t s (work due
are g e o m e t
is p o s s i b l e
two-variable for
sus
fro m a l g e b r a i c
In p a r t i c u l a r ,
st at e s mod e l
conjectures
latter
this
a s k e t c h of
polynomials.
to his
of
then d i s
the c y c l i c
the c l a s s i c a l
odd n u m b e r
contains
applications
century-old
sta te s
exotic
We g i v e
the p r o d u c t
it
a nd
t h ree-
We
cyclic branched
the e i g h t - f o l d p e r i o d i c i t y
The a p p e n d i x
We d i s c u s s
(The
t he o ry d e r i v e d
of Se i fert.
2 ( k ,2 ,2 , • • • , 2 )
about
space.
the or y
discus
of e x a mp l es .
s u s p e n s i o n a nd
of
This
the e m p t y knots,
about
setting.
ering m et ho ds
its
in kno t
topology the
as p r o j e c t i v e
co nstructions.
the c o n s t r u c t i o n s
folds ar e
c ov e r i n g s .
examination
fibrat i on ,
the
relation with
dodecahedral
the c y c l i c
struction many their p r o p e r
as
to
Brieskorn varieties
2 (2 ,2 ,2 )
of
2(2,3,5)
ric c o n s t r u c t i o n s
tion
its
We d i s c u s s
by d e t a i l e d
pension and product
h ow
an d
relationship with branched
sion p r o c e e d s
cuss
introduction
using
s et t le to K u n i o this
xi v
PREFACE
Knot
t h eo r y
topology.
It
a d e ep u n d e r p i n n i n g
is a b e a u t i f u l
ramifications these p a g e s
comprises
that
spread
reflect
With great
this
s u bj e c t
in its
throughout
all
C a r m e n Sa font,
Esteban
I n d u r i a n an d E l e n a M a r t i n
for
through
tangled
thanks
Vaughan
Jones,
Pila r
terrain.
covering
Special
an d
J o a n B irman,
M a r i o R as e t t i ,
Sostenes
c on ver sations.
Special
Ra ndall
Cameron Gordon the
texts
knots Ms.
into
Illinois of
the
f irst
draft,
the U n i v e r s i t y producing
the
of
an d
Iowa
final
drawing
of an
Ra y L i c k o r i s h , Dennis
Massimo Agnes
to my
infinite
Ro s em a n,
Ferri,
for h e l p f u l
stude n ts ,
Ivan
an d m a t h e m a t i c s ,
and
to all
on
my
to D a l e R o l f s e n
i n t r o d u c i n g me
tale.
the
I am g r e a t l y
g-signature
of C h a p t e r s
thanks
at
for
text.
14
18.
last
typing
mathematics
of
this
of job
typist
collaboration
st ages
s lice
To
the U n i v e r s i t y
extraordinary The
to
to
to w e a v e
theorem and
for an e x c e l l e n t
to A d a Burns,
those
indebted
in a l l o w i n g me
Head Math Typist
at C h i c a go ,
journey
for
the e x p o s i t i o n s
S h i r l e y Roper,
this
Joseph Staley
tangled
work
Rodes,
listening and
for his g e n e r o s i t y
of his
Maite
for
of n a t u r e love a
May
Winker
to n e w
that
sharing
Jon Simon,
al s o
and Steve
to F r e d e r i c k
f ri e n d s
his
Alvaro
H u g h Morton,
thanks
contributing, realms
Valle,
Lins,and Corrado
Weiss,
with
of g e o m e t r y .
to K e n M il l et t ,
Larry Siebenmann,
K e i t h W o l c o tt ,
H an d le r ,
del
to r e p r o d u c e
space,
right,
I thank Jose M o n t e s i n o s ,
L ozano,
cyclic
own
spirit!
pleasure
for k i n d p e r m i s s i o n
of g e o m e t r i c
at
in
project
PREFACE
we r e p a r t i a l l y and of
s u p p o r t e d by O N R G r a n t No.
the S t e r e o c h e m i c a l Iowa,
xv
Iow a City,
Topology
Project
N0014-84-K-0099
at
the U n i v e r s i t y
Iowa.
C hi c ag o ,
F e b r u a r y 1986 an d Iowa City, D e c e m b e r 1986
On Knots
I INTRODUCTION
These notes
constitute
k no t
t he o ry
that
is
Trip
[FI].
We
ly,
sometimes
Y,
also
st ru c tu r e,
is kn o t
studies
the p l a c e m e n t X
and
is Y
S
3
S
is E u c l i d e a n
then we h a v e
X
1
or
Y
kn o t
the e m b e d d i n g s
of
2
the
three-sphere
of
IR3 .
S
3
2
is
a "knot
the one below.
that knot
s pa c es
Y.
Here
often means
(isotopy,
for
X
an d
the ho w
up
to
exam p le ) .
2 2 = 1, x a n d y real} = { ( x , y ) | x +y
The
theory. S
= { ( x , y , z , w ) | x +y +z +w
like
sometimes
three-space
classical
course,
in
is
Given
classify
= { (x ,y ,z ) |x ,y ,z real
2
Of
One a n s w e r
problem-'
a nd
of
the c i r c l e
IR
studies
occasional
w ith p h i l o s o p h y
m a y be p l a c e d w i t h i n
form of m o v e m e n t X
to
of F o x ’s Q u i c k
to d i g r e s s
sometimes
t he o r y a b o u t ?
is u s u a l l y an e m b e d d i n g ,
If
free
sp ir i t
in the d i r e c t i o n of a p p l i c a t i o n s ,
classify how
some
feel
in the
introduction
ideas.
W ha t th eo r y
leisurely
(we h o p e! )
shall
w i t h an a n a l o g o u s general
a
2
1
in
n u mb e r s } , Classical
3 IR
or
= 1; x , y , z , w
the o n e - p o i n t
on a rope"
ma y
corresponding
3
knot
th eo r y
in real}.
Note
that
compactification
follow a pattern c las sical
kn o t
is
4
CHAPTER I
o b t a i n e d by
splicing
introducing new
the ends
of
the
rope
to g e t h e r
tangling):
T
Once
the ends
kn o t tednes s .
( w i th o ut
are
spliced
The u n k n o t
t o g et h er U
it
( tr e fo i l)
is p o s s i b l e
to d e f i n e
is r e p r e s e n t e d by
U a n d a kn o t
is
said
to be u n k n o 1 1 ed
if
it can be d e f o r me d ,
CHAPTER I
without
Thus
tearing
the rope,
the
fo r m
The
trefoil
knot te d .
W
Th i s
above T
proving knottedness,
an d
n ess
to
that g i v e s There
an d we
are
shall
(I c a l l e d p ar t is
sent
knots.
different
use m o r e
a p p r o a c h will
here
rise
be of
it
turns
into
the u nknot.
is u n k n o t t e d .
(two
requires
unt i l
5
sketches
proof!
A nd
a b ov e ) it
is
of c l a s s i f y i n g the n e e d way s
for a
is a c t u a l l y the q u e s t i o n
types
to a p p r o a c h
s uc h a The
c o m b i n a t o r ial a n d p i c t o r i a l
to c l o s e l y a b s t r a c t
K not the
Theory
theory,
first kn o t
in [Kl].)
rope d r a w i n g s
becomes
of k n o t t e d -
t h e o r y of knots.
than one ap p r o a c h .
it Fo rm a l
of
that
theory. The
idea
repre
CHAPTER I
6
We
call
the p i c t u r e
contains
all
k no t
of
out
embedding y o u mu s t
rope a n d
understand
of
the c u r v e
Thus
we
st ar t
or b e l o w
rig ht a k n o t information
it p r e s e n t s
of a circl e ,
lift at
the
the n e c e s s a r y
p ar t
and
on
S
1
,
IR
that a b r o k e n
undercrosses
with a planar
the c r o s s i n g s
the p l a n e at
to
these
for
line
To
see
fo r m this
in dicates
the o t h e r
It
constructing
a specific 3
in
diagram.
the
for an embedding where
one
part.
graph
for m a c u r v e crossings:
w h i ch dips
above
CHAPTER
There
and n
are
t wo
hence
2n
at
potential
each
crossing:
knots
for
each
planar
graph
with
cros s i n g s . The
these
theory
notion
of
topology
can
then
And
we
spaces)
of
history,
and
Many
3
as
to
these will
in the
we
explain
this
way
theory
apparatus
with spaces. be
used
possible.
of
spaces Z,
and This
later
in
is
a:S
complementary
generalizations are
once
embedding
construct
associated of
begin
the the
also
topology
— » S
knot
apply
can
We
approach
t he
the
1
commences
diagrams. Another
S
choices
7
I
1
how the
to
S
algebraic (such work
as with
3 3
section.
the
and -a(S
1
abstract
to
study
) = Z. to
branched
covering
the
algebraic
also
in
notes.
of
the
initial
Two
are
particularly
Z.
has
a
placement
long
problem
worth
men-
tio n i n g . a)
S n — > S n + ^,
the
study
of
the
We
topology
approach these
deform
next
t ake
— » S
space
to
embeddings
of
an
CHAPTER
8
n - d i m e n s i o n a 1 sphere s i on s b)
I
into a s p h e r e
of
two d i m e n
higher.
W n — > S n + ^, being
same as
embedded
(a),
but
we a l l o w
to be an a r b i t r a r y
the
s p ac e
manifold.
3
One A
c an a l s o
link
in
S
look at 3
is a n
1 inks
in
S
embedding
and
in h i g h e r
of a c o l l e c t i o n
spheres.
of
c i r c le s .
Thu s
is
the
simplest
fascinating clude Rings, its
this a
example
phenomenon introduction
link
components
that ar e
of a of
li n ke d
link.
Linking
three-dimensional
with a picture
exhibits unlinked.
a
tr i a d i c It
is
of
space.
We
con
the B o r r o m e a n
r e l a ti o n:
itself
is a
any
linked.
two
of
II LINKING
Ou r IR
f irst
NUMBERS
model
for
AND REIDE MEI STE R
the
theory
of k n o t s
We
that
is c o m b i n a t o r i a l ly based.
diagrams sequence K'.
K
and
K'
Equivalence
is a c o n t i n u o u s the other.
is d e n o t e d
diagrams
by
(see the
if
and
two k n o t
there
[R 1])
links
changing
sy m bo l
as
Reidemeister isotopy
of R e i d e m e i s t e r
through
proved
the
embeddings
moves:
1.
Reidemeister
9
Moves
There
a re
link
a K
in
into K ~ K'.
that
f r om
there
one
converse— making
iden t ic a l.
in
or
exists
are am b i en t iso top i c . m e a n i n g
deformation
lence a n d a m b i e n t
say
e q u i v a 1ent
of Re i deme i s ter m o v e s
Equivalent
types
ar e
MOVES
three
to
equiva basic
10
CHAPTER
It locally o t h er in
is u n d e r s t o o d on
the kn o t
strands
the moves.
is no t a that
o rd e r
pedantry,
Example:
but
is a l s o
locally
We
move
of
type
is a " h i g h e r
I i nv i t e
moves.
It
a re
o th e r
to b e p e r f o r m e d
understood than
that
no
those d e p i c t e d
Thus
example
And
these m o v e s
d i a g r am .
present
legitimate
this
agre e !
a re
that
II
him/her
i n sist
here
to s i m p l i f y
the
1.
order"
to
The
reader
move
formulate
of a
may
type
t he o r y
on p u r e
m oves
not
out
theory
(read
on!).
feel 1.
I
of h i g h e r of
CHAPTER
It
is a l s o
callv
understood
eauivalent"
that
ar e
II
11
two d i a g r a m s
eauivalent.
that ar e
"topologi-
T h us
an d
T hi s
part
moves. IR
of
We
that
get
thr o ws
K ~ 0 the
equivalence
really mean
E x e r c i se 2 . 1 . that
the
beyond
the R e i d e m e i s t e r
there
exists
a homeomorphism
one u n d e r l y i n g g r a p h
Give
an
ex ample
(the u n k n o t )
equivalence
E xe r c i se 2.2.
that
go e s
Prove
a nd
to
of a k n o t K
of
the other.
diagram
requires
a
type
K
such
3.
move
to
started.
that
the
following
process
will
always
CHAPTER
12
produce
an u n k n o t t e d
encounter start,
a previously
(------ )
Call
line,
dr a w i n g .
undercross
walking along
Whenever it.
we
crossings
say
more
than one
component
of a u n i v e r s e
link of
4-valent
is a
yo u
Return
to
are
vertices
trefoil
component
I mean a curve
the g r a p h a n d a l w a y s
components or
by
graph with
Th u s
may have
Here
Also,
a planar
a uni ver s e .
Such a graph
a knot
drawn
Start
eventually,
E x e r c i se 2 . 3 .
The
d i a gr a m:
II
as
un i v e r s e . in
obtained
c r o ss ing at
by
a cros s i n g .
the p o t e n t i a l
components
of
the p r o j e c t i o n .
that a k n o t
alternate
under
or —
link over
is a l t e r n a t i n g -- u n d e r
—
if
over
its -
•••
as
CHAPTER
you
traverse
any
component.
13
II
is
Thus
alternat-
ing . Prove:
Any
k n o t or
1 in k .
We the
now
universe
consider
components,
and
is
the
projection
of
2-componen t 1i nks . we
orient
them,
then
an
If we
alternating
a
and
wish
are
P
to
define
a
3 linking
number
Ik(a,|3)
=
lk(L)
(where
L
= a U
j3 C
S
)
so
tha t
This to
do
will this
conform we
with
associate
the a
usual s ig n
r i g h t - h a n d - r u 1e . e
to
each
In
crossing.
order
CHAPTER
14
DEFINITION. Let
a fl P
Let denote
L = a U P
II
be a link of
the set of crossings
two components.
of
a
with
(5.
Then
This
formula defines
the
linking
number
for a g i v e n d i a g r a m
Exam pIe :
lk(a.|3)
=|
E x a m p Ie :
lk(o.jB)
=
Example :
lk(a,/3)
=+2.
E x a m p Ie :
lk(a,p)
=0.
\
( 1 + 1)
=
1.
(1-1) = 0.
CHAPTER
This
last
l i nk e d
example
even when
is J.H.C. their
15
II
Whitehead's
linking number
link.
Links
can be
is zero.
[ A n o t h e r v e r s i o n of the W h i t e h e a d link]
E x e r c i se 2 . 4 .
THEOREM.
of a m b i e n t
lk(L)
last
and
L'
= lk(L').
exercise
of
links
really
Borromean
L
oriented
Linking
number
2-component is an
invariant
Istopy.
invariant ar e
the
L ~ L',
If
l i n k s , then
This
Prove
links
r i ng s
ar e
Let
that
the
at
and gives
linked!
E x e r c i se 2 . 5 . differ
shows
not
L site
that us
But yet
a nd of
lk
our
is a
f irst
topological
proof
the W h i t e h e a d
that
link a n d
some the
c ap t ur e d.
L one
be
two
two-component
cr o s s i n g ,
as
links
s h o w n below.
16
CHAPTER
G i v e n a kn o t
or
link
W,
II
define
1
if
W
has
one
component
0
if
W
has
more
is o b t a i n e d
from
C(W)
Suppose
that
W
than one L
or
component. L
by
splicing
out
the c r o s s i n g :
Show: lk(L)-lk(L)
(This
is a
to g i v e
new
triv ia l
Prove
tion p r e s e r v i n g
Mobius
=
but
the p a t t e r n w ill
generalize
invariants!)
E x e r c i se 2 . 6 .
h( M^ )
exercise,
= C(W)
t here
h o m e o m o r p h i sm
where bands,
that
and
respectively.
d oes
not
3 3 h :IR — » IR are
r i gh t
exist
an
s uc h and
orienta-
that
left
handed
17
CHAPTER II
Consider
(Hint: with
its
a
linking n umber
of
the
c ore
of
the b a n d
e d g e .)
E x e r c ise 2.7.
Link,
Twist,
W rithe.
N ot e :
and
(Isotopies Hence
we
ca n h a v e
where
twi s t ing
relative
situations
to
the e n d - p o i n t s )
w i t h a d o u b 1e - s t r a n d e d
link
18
CHAPTER
is e x c h a n g e d
For
for wr i th ing
an a p p r o p r i a t e
T(L)
= twist
can p r o v e
II
of
c la s s
L
an d
of 2 - c o m p o n e n t W(L)
= wr i the
lk (L 1 = T fL 1+ W ( L ) .
You
links of
L
L
define
so
that
you
should have
T
T
T hi s
fo r mula,
gists an d and
0
lk(L)
studying
[ B C W ] .) W
= T(L)+W(L),
c l osed,
You
can
by p l a y i n g
,
1 .
W
has
d o u b 1e - s t r a n d e d
see
the e x c h a n g e
w i t h a r u bb e r
E x e r c i se 2 . 8 .
Classify
the wa y s
wrapped
around
a c y li n d e r .
battery
problem
a small
transistor
[This
by B r a y t o n Gray. battery.)]
band
been used DNA.
(See
phenomenon or a
a rubber
by b i o l o [ W H ] , [FB] between
telephone
band
T
cord.
can be
is c a l l e d
the
rubber
(He w r a p s
his
band
band,
around
Ill THE CONWAY
We n o w kn ots
and
variant [Cl], by
links.
of
It
a more is
[K2]).
This
1.
To
each
Alexander
v ^(z)
receive
identical
AXIOM
2.
If
K ~ 0
AXIOM
3.
Suppose one
K
Remarks.
or
€ Z[z].
invariant
three
c r o s s i n g as
K
Equivalent
(the u n k n o t )
that
lin k
of
oriented
(see
[Al]
and
is d e s c r i b e d
then
knots
there knots
The
r in g
or
v v = 1. K.
links
differ
at
the
s h o w n below:
(We call
Z[z]
and ,.
K
- Vrr = z v T . K. L
is a s s o c i
K ~ K'
polynomials:
K
then
polynomial
polynomial
o r i e n t e d k not
l inks
of
invariant
axi o ms :
ated a polynomial
site
powerful
the C o n w a y p o l v n o m i a l . a r e f i n e d
the c l a s s i c a l
[Kl],
three
AXIOM
introduce
POLYNOMIAL
is
L
this
the
19
the e x c h a n g e
rin g
i d e n t i tv . )
of p o l y n o m i a l s
in
z
20 with v K (z)
CHAPTER
integer
coefficients.
Thus
these a x i o m s
2
= a Q f K J + a ^ ( K ) z + a 2 (K)z +•••
n = 0
,
V v (z)
is a p o l y n o m i a l ,
z er o
III
1
a n (K) v / € Z
on a g i v e n As we
these
kn o t
shall
these
for
see,
invariants
is a n
are
n
except
where,
invariant i nt e g e r
assert
for
each
of
K.
that
Since
invariants
are
all
sufficiently
large.
for
a ^ , a^
and possib ly
What
they m e a n g e o m e t -
mysterious!
do
a^,
r ic a 1 l y ? The related
axioms to
exchange & Axiom a^,
the
do a s s e r t invariant
relation:
3).
We
a
shall
an d
to p r o v e
For
now,
that
each
a^f K)
invariant
that
we a s s u m e
.n (K) n+1 v 7
is
by a c o r r e s p o n d i n g
..(K)-a (K) = a (L) n+1 v 7 n+1 v 7 nv 7
use
a
this p r o p e r t y the a x i o m s
a re
consistency
to
(translate v
interpret
a^
an d
co nsistent.
and
set up
some
calcula-
t io n s .
LEMMA
3.1.
[ R ec a ll with
If
that
diagram
disjoint
a
L
link
is a split
is
containing
neighborhoods.
is a spl it
link.]
split
link
if
it
then
is e q u i v a l e n t
two n o n e m p t y Thus
= 0.
parts
that
to a live
link in
CHAPTER Proof.
If
two p a r t s We m a y below.
then K
vL
■
split
strands
K
Axiom
ar e 1.
21
then we m a y a s s u m e r e l a t e d as
fo r m a s s o c i a t e d and
^
For
is
with
VK = VK = °.
L
III
shown below
links
K
equivalent Therefore
its
and
via a 0 =
K
diagram on
the
as
shown
217-twist. - v^- =
has
right.
Hence ’
hence
example-
Re ma r k.
You may
enjoy
can be a c c o m p l i s h e d
Hint.
Prove
proving
the
lem ma
via Reidemeister
a generalization
of
type
that
moves.
2 move:
the
217-twist
22
CHAPTER
We us e For
the
fact
a proo f,
that
see
isotopic
varying
continuously
arising
small
the
embedding
The
lemm a
OOOO easy
and
to do
in
or
links
is a f a m i l y t
su c h
to a m b i e n t isotopy.
of
that
K,
K'
Kq
= K
that
the f a m i l y v a r i e s s mo o t h l y . context
neighborhood is
of a n y
IR
tame
point
= K'.
or S
3
are K nots
(in a
on
the k n o t
or
standardly unknotted). us
that all
receive
recursive
ar e
in
and
the e m b e d d i n g s
in our
ar e
embeddings
that
tells
,•••
Two knots
there
fr o m d i a g r a m s
sufficently link
if
we m a y a s s u m e
differentiable
is e q u i v a l e n t
[Rl].
ambient
Here
~
III
of
the v a l u e
the u n l i n k s : 0
from
v.
O O , It
o o o is n o w
calculations:
Examp 1e 3.2
vK = 1 + z2
CHAPTER Example
3.3:
& oS
L
He r e
L
lk(L)
= 0.
tion
is
L
the W h i t e h e a d We
similar
and h enc e we get
23
III
see
link
that
L ~
to E x a m p l e
3.1)
=
v^ -(-z)
1+ z
.
= z(l + z
from C h a p t e r an d
we h a v e
Putting
2
W
this
II.
thus
Thus (by c a l c u l a
Vj- = - z .
W ~ &
information
together,
).
3 •
Example
3.U:
•
v t
z
•
€0
We n o w h a v e
d en o t e
Thus
=
with
~
and
2n
W ~ U.
crossings.
Therefore
v y -z = z • 1
2 vT
= 2z.
2
>
%.
For
Let
e x ample,
L
24
CHAPTER
T he
same
reasoning
(by
III
induction)
sho ws
that
= nz. n
Since the
l k ( L n )= n = a ^ ( L n ),
coefficient
relation with
DEFINITION by
the
of
z n in
v^]
L
Let
we b e g i n
a^fK)
to g u e s s
is
a
be an y
knot
or
link.
C(L)
Define
formula fl = I [0
T hu s
C(L)
knots
a nd
links.
LEMMA
3.6.
Let
andz
respectively
if
L
has one
if
L
has m or e
is an
i n v a r i a n t of
a^
a^
and
a ^f K )
=
(ii)
& 1 (K)
flk(K) = {
(i)
Let
Then
3l q (K)-3Lq (K)
this
coefficient.
K,
and
it
denote
K
is
Since
e x a mp l e,
us e E x e r c i s e
t ran smute
to w h e t h e r (ii)
2.5.)
the
knots
when
an d
This
that
d i s tinguishes
coefficients
K
and
ha s
1
of
Then K,
links
two c o m p o n e n t s ,
o therwise.
= 0
switches
= C(K).
L
C(K) for all
switching.
according
than one c o m p o n e n t .
the C o n w a y p o l y n o m i a l .
in
(i)
Proof.
component,
( R e p e a t e d f rom E x e r c i s e
[ 0
a Q (K)
that
l i n k i n g n u mb e rs .
3.5.
C(L)
strand
[re c al l
L
the
says
be
statement that
there K
Again
a^
exists
of is
we one
let
see
that
or m o r e K,
K,
in A x i o m
the a x i o m invariant
a sequence
to an u n k n o t
2.2.), it has
r e l a t e d as
L
=1
components. be as
for under
of
or u n l i n k a^ ( K)
3.
(For or
0
Hence
in A x i o m
3.
25
CHAPTER III
Then
a^(K)-a^(K)
= C(L)
leave
the
the pr o o f
rest
This validity
of
s e c t i o n will of
foil.
3.7:
We w o r k
Watch
K
has
two c o m p o n e n t s .
as an e x e r c i s e
[Exercise
end w i t h a d i s c u s s i o n
our a x i o m s v i a an
coefficients.
Example
when
inductive
first w i t h m or e
the c a l c u l a t i o n
of
We
3.6].
the
definition
of
the
e xa m pl e s.
of
a^fK )
for
the
t re
We h a v e
K
K
L
a 2 ( K ) - a 2 (K) = lk(L)
[Notation.: lk(L)
= 0
Let if
lk(L) L
= a ^(L)
does not
&
have
number ings
on
sense, that K.
= lk(L)
= a2 (U) = 0
a 2 (K)
= 1.
is o b t a i n e d
Thus
L
a 2 (K)
a 2 (K)
link.
two c o m p o n e n t s . ]
K a 2 ( K ) - a 2 (K)
this
or
3>
K
In
for a n y k n o t
computes from
= 1
a kind
of
links m a d e by
"self-1inking” splicing
cross
26
CHAPTER
3.8:
Example
Note
that
Problem:
K
becomes
numbered
1,
need
some
for
2,
and
III
Calculate
unknotted
3.
if we
Obviously
notation
to h e l p
a^( K )
at
keep
for
s witch
this
crossings
point
there
is
the
tra c k
of
the
calcula-
r es u l t
of
switching
result
of
eliminating
t i on . (i)
(ii)
Let
S. ( K)
. th l
. crossing
Let
(iii)
denote
E ^ (K )
denote
i ^
crossing
Let
e^(K)
for a n y
of
denote
cr o s s ing of
Then
of
link
the
the
K.
the K,
the
the
by a splice.
sign
of
the
i
K.
k n ot
or
K
with
indexed
crossings,
W
K >-a n + l(S iK ) = - i ( K ) a n (E.K).
3 becomes
Axiom
CHAPTER
Using
this
notation
we h a v e
: (ej
= ^(K))
a 2 ( K ) - a 2 ( S 1K)
= tjlkfEjK)
a 2 ( S 1K ) - a 2 (S2 S 1K)
= e 2 l k ( E 2 S 1K)
a 2 ( S 2 S 1K ) - a 2 ( S 3 S 2 S 1K)
Since
S3S2S jK ~ 0 a 2 (K)
we
27
III
= &3 1k (E ^ S ^ ) .
conclude
that
= e 1 l k ( E 1K ) + e 2 l k ( E 2 S 1K ) + e 3 l k ( E 3 S 2 S 1K ) .
•
K
i
e i
=
-i
= +1 3 = _1
r lk(Xj) = 0 i
l k ( X 2 ) = +1
*• l k ( X 3 ) = 0 •
X 3 = E 3 S 2 S 1K
Note
that
this
calculation
is
sufficient
a 2 (K)
to c o n c l u d e
=
1
that
28
K
CHAPTER
is kn o t t e d . In g e n e r a l ,
signed
moves,
as a c e r t a i n it
is an
a "candidate"
a (K)
and
of
pa r e
that
invariance w i t h B all
restrict exactly
the
in
the
Take
a sum of
f o r m u l a above.
That
is,
(Denote universe
crossing Example’
end we
to h a v e
f r om a
the
that
first
time.
shall the k n o t
unknot
to
as
the kn o t
is not
--- •--- .)
over-crossing
(com
to
in
f ol l o w i n g :
corresponding
of
defi
the p r o p e r t i e s
that u n k n o t standard
to
shall
that we
the d i r e c t i o n
the
then
is
as
for
and
in [BaM])
the b a s e - p o i n t
an
this
via
to def ine
this a p p r o a c h
it
create
try
to
on
in
To
invariant
The key
we do
a base-point
to
linking numbers
sequences
arise
is an
is n a t u r a l
to be p r o v e d a^fK).
that
lk(K)
i nv a ri a nt .
the u n i v e r s e
Choose
it
and Mehta
2.2.
how
sum of
switching
t hose
Exercise
and
as
we u n d e r s t a n d
the R e i d e m e i s t e r a 2 (K)
ca n be e x p r e s s e d as
a 2 (K)
Since
prove
a 2 (K)
linking numbers
CREATING
(a)
III
a cr o s s i n g . Walk along
the k n o t ' s each
K.
the
orientation
time y o u
cross
a
CHAPTER Let
KP
denote
operation. upon
t hose
The
K
spe cific
tation fro m
an d
the
n-i+1 this
and
diagram
label
in
this
depends
orientation. by
different.
the kn o t
by
1,2, ••• ,n
To
fo r m
its d i r e c t i o n
L ab e l
the
f irst
this of
orien
crossing
set
the
in K
that
s e c o n d by
the
i ^
d iffer
n-1 ,
f rom
crossings
and ge nerally
new crossing
from
D
in
label
that
KP } by
is met in
t r averse. This
s uc h
that a re
the b a s e - p o i n t .
D = {crossings n,
is p r o d u c e d
unknotted
K P .We will
traverse
from
29
that
of b a s e - p o i n t
crossings
labelling
by
the u n k n o t
the c h o i c e
Compare
III
gives
that
sequence
S S • • • S 1K = K P n n-1 1
a s tandard standard
a switching
sequence
sequence
for
is u n k n o t t e d .
the o r i e n t e d
depends
upon
SgSjK
= Kp .
^ i ’^ 2 ’ * * * ’^n
K
knot
and
Call K.
the
this
The
choice
of
base-po i n t .
Example:
Each where
crossing it
is
is
f irst
labelled
(in
traversed.
the o r d e r
n, n - 1 , • • , 1 )
30
CHAPTER
DEFINITION
3.9.
S j , • • • ,S
be a s t a n d a r d u n h n o t t i n g
e. = e.(K) l lv J
of b a s e - p o i n t , to do
l
the
sh o w
oriented k n o t .
,S.
l -1
l -2
ci(K)
that
it
(i =
1
is
is a
sequence
• • -S.K
a(K)
formula
that
an d
this
be an
E.S.
X. l
by
We m u s t
o r de r
Let
and
a(K)
Define
K
III
v
=
K.
for
Let
1 , 2,•••,n).
J
e^lk(X.).
independent topological
a preliminary
Let
discussion
of
of
the
choice
i nv a r i a n t .
In
the u n k n o t
is r e q u i r e d .
UNKNOT
DISCUSSION
L et's verse
think about how
fr o m
p,
K
K
m a y look
I
I
I
an d
KP
dif f er .
As
Th e
crossing
encountered w ill
look
I
lab elled when
like
• * •
I
I
i
is
I
t
* * *
and
i
i
the
first u n d e r c r o s s ing p.
As
a result,
will
1a b e 1 s the
be
I ---I I* •••
I
changed
first
I to an
over-crossing
c ro s s ing c h a n g e
be t ween
in K
Kp . Let's
KP
this:
p I I is,
K.
I
t r a v e l l i n g f ro m
I I
That
tra
like:
-------------------- i-------------------P
we
consider
the
>-•-- ----- K
p i
following
si t ua t i o n :
i
»-•---- :--- K
p 11
p
KP , and
CHAPTER
Here
the
s ite
of
fi r st the
crossing
fir s t
s t ances
that
crossing
i_s a split
III
31
occurs
after
change.
Under
p
is a l s o
the
the s e c i r c u m -
un 1 ink .
Example:
E^K^,
We
leave
the p r o o f
PROPOSITION a(K ) ,
Then of
base-point
point
Let
on
a.
To
suffice
emphasize
write
it ma y
K
s li d e
an
exercise.
be an o r i e n t e d h no t is
unlin k .
independent
diagram. of
the
choice
K.
through a crossing
we will or
this a s s e r t i o n as
as d e f i n e d ab ove,
It will
P roof.
of
3.10.
of
a spl i t
to show in
K
that
without
the p o s s i b l e
a ( K, p ). under.
Now This
we
can
changing
dependence
the b a s e - p o i n t leads
s l id e
to
two
the b a s e the v a l u e
on b a s e - p o i n t
may
s li d e
cases'-
over
32
CHAPTER III
Case
1.
--- »-•—
----
P
Here
K
and
KP
under
the c r o s s i n g
p
K
differ to
i
at
q
i.
i
crossings
are
the
and
Kq .
Thus
for
K
i.
and
And .
not
if
is a
then
a(K,p)
Case
K
and
KP
u n li n k.
and
the c r o s s i n g sequence
f rom
the u n k n o t
crossing.
The
KP .
s li d e
If we
labelled
for
I
proving
Case
discussion
l k ( E n K P ) = 0.
K
a nd
the
over-crossing
p
I
jl
'k
i
across
q
d o es
that
E KP n
Hence
--- »— •--------------
11
crossing
Since
I
1.
P
I1 I kp
line
just
Ik on
K
sequence
E S 1 - « * S 1K = E K p . n n-1 1 n
»— •-:--------
lies
between
= e ^ k f E ^ ^ • • • 'SjK) .
Therefore
2.
p
as
changing
we h av e
P
Here
all
is a stanc*ard
* S a stan-•---- -----
not
change
f rom
then
*
i Kq
prior
q
to K
the to
CHAPTER the
crossing
added If
one
the
d oe s
crossing
switching S
with S
n
between
the
set
sequence
for
,S
to
33
K
of
and
Kq .
changing
K t Kq
Thus
we h a v e
crossings
of
KP .
is
1 , • • • ,S. , fS.,S. , , • • • , S t n-1 l+l 1 l-l 1
switching
,S n n - 1
K,
change
III
the c r o s s i n g
-,,S. i+li-1
l abelled
i,
is a s t a n d a r d
1
then
sequence
for
KP . Thus
and
the
a (K,p)
f i r st are
the the
a n d all
i t^1
terms
i de n ti c al .
l k ( E ^ S j _ j • • #S ^ K ) . a(K,p)
i-1
the
crossing.
This
the
Then
term
remaining Note
in
for
a(K,q)
a(K,q)
has
the
term
is m i s s i n g
f ro m
the
sum
terms
that
sums
differ
by a s w i t c h at
suc h a s w i t c h
will
affect
linking numbers £ k + i l k (E k + is i+ k - r - s i+ is i - r ” s iK ) ~
k 'kP
e k + i l k (E k + is i+ k - r * * s i+ is is i - r " s iK > — only
for
i f the c r o s s ing
p o n e n t s o f the only
if
Note
that
that
the
(k+i)
l a b e 11ed
r e s u l t ing label s
And of
= e^ C ( E ^ X ) .
the d i f f e r e n c e s
.k ^
is a c r o s s ing of
a crossing
lk(X)-lk(S^X) sum of
1i n k .
i
k
this
is
true
we
yields'.
a (K ,p ) - cl (K ,q ) = - e i l k ( E . S i_ 1 * * - S 1K)
com
if a n d
two c o m p o n e n t s
Therefore
two
+ e.A
of E ^ .
conclude
34
CHAPTER
where
A =
the
is a c r o s s i n g We al s o
sum of
know
unlink
for
first
return
just
indices A =
whose
lk(E
pletes
of a
backwards
k = 1,2,•••
t he
E.S
1 n
same
prior
link
2 and
Case
the p r o o f
2 of
unlink. through
it,
t he
switching
to
(i
S^S^S^K p
set
this
is
Since of
the the
link
crossing
implies
= a(K,q).
that This
com
the p r o p o s i t i o n .
Proposition
Here 1
of
k+i
is a
1
as b e f o r e
s u m of a n y
unlink
that
E^K.
the b a s e - p o i n t ) .
the
switchings
such
. • • • S . .S. n-1 l+l l-l
reasons
to
is
S
of
Hence a(K,p)
(for
is a s p l i t
from
that
S
Case
Example
e, . , k+i
two c o m p o n e n t s
split
ing n u m b e r
of
III
3.10):
~
.
(as b e l o w )
sequence.
Note
If w e
that
slide
then we will
E^Kq
q lose
CHAPTER
Here
S ^ K N ow
III
35
~ KP .
compare
the
computations
for
q
and
p.
a ( K , q ) ____________________ a ( K . p )
We
see
ut e d
clearly
across
Rema rk . fully, matic
how
the
If y ou you
will
properties
the
ot h e r
linking n umber terms
examine see of
in
the c a l c u l a t i o n
the p r o o f
of
that we a c t u a l l y the
linking
l k(E^K)
is d i s t r i b of
Proposition used
number.
exactly Th a t
is,
a(K, p) .
3.10
care
the a x i o that
36
CHAPTER
lk(X)-lk(S.X) cal
= fc.(X)C(E.X),
invariance.
and used axiomatic
properties
a ^( K )
terms
in
way,
we
ance
for
This
is
create
of an
rather
of
the
for
a(K) using
of
creating
topologi
corresponding
= a^(K), the
and
c a n be g e n e r a l i z e d
the
then we
c an d e f i n e
same a r g u m e n t .
definition
sequence
reminiscent
= 0,
this p r o o f
we p r o v e
inductive
like
is c e r t a i n l y
Once
a^
the w h o l e
it
{ >.
lk(OO)
As a result,
inductively!
III
an d p r o o f
coefficients
something
In of
this invari
a ^ ,a ^ ,a ^ ,•••.
fro m n o t h i n g !
And
of
the V o n N e u m a n n p r o d u c t i o n
{{
} {{
ordinals
{{
}}.
{{
} {{
}>}.
}}
{{
} {{
}}}}•••■
E x e r c i se 3.11.
K
(a)
Work
out
a(K,q)
fr o m
(b)
Work
out
a(K,p)
an d
wi th (c)
this
d i ag r am .
compare
your
calculation
(a ).
Simplify
the d i a g r a m by R e i d e m e i s t e r
gram
K'
with
Find
v j( / •
fewer
crossings.
F ind
moves
to a d i a
a(K').
CHAPTER III E x e r c i se 3 . 1 1 a . amine
both
This
exercise
linking numbers
37
is d e s i g n e d
and
the p r o o f
to h e l p
of
you
reex
Proposition
3.10. (i)
Let
L = a
U J3 be a
Let
l , 2 , # # , ,n
s uc h that
link of
be a set
two c o m p o n e n t s
of
S S . •••S. L n n-1 1
crossings
is a split
of
a ,f3. a
with
j3
link. S h o w that ----- -----
l k ( L ) = 6l ( L ) + e 2( L ) + - * - + e n ( L ) .
Example:
S ^L lk(L)
(ii)
Let
L = a U /3
Let 1 , 2 , •••,n that
be
= e 1(L) .
link of
a n y set is
= 2^_^e^(L)
C
(E^L)
some e x a m p l e s of u n k n o t
1on k n o t s a n d z er o
on
a ,(3.
in L
s uch
S h o w that -- — -----
C
as
defined
in
links.
diagrams
that a r e
not
u n k n o ts .
ha d
started
the d e f i n i t i o n
s ho w
link.
where
Give
as
crossings
a split
is
If y o u
two c o m p o n e n t s
of
3.5,
standard (iv)
be a
S S. • • • S . L n n-1 1
lk(L)
(iii)
= -1
split
that
i nvar i a n t ?
it was
with of
the
formula
l i n k i n g n u mb e r,
well-defined
an d a
in
(ii)
(or
(i))
h o w w o u l d yo u topological
38
CHAPTER
III
E x a m p Ie :
L
Switching opposite N ow
the
two
sign.
Therefore
onward
to
We h a v e
Re ma r k.
starred
(one
c omp onent).
just
as
easily
untangling
one
for
links.
the a v e r a g e
of
to
links;
a' value
it will
procedure
linking n um ber
as
of
a(K)
unlinks
(Define
by
this
o n e - h a 1 f of
is
w h at the
s ai d w o r k s sequence
independent
over
be d e n o t e d
is e x a c t l y
h av e
is a k n ot
we h a v e
Then
a.
K
a switching
summing
of
They
i nv a r i a n c e .
o nl y w h e n
Show
L.
= 0.
everything
component.
t ak i n g
this
the p r o o f
H ow e v e r ,
Now define
that
lk(L)
defined
point.
a
crossings
all
of
components
a'
is
the
a
as
befor e .
by
we do
sum of
w h e n we the
by baseand
extension Note
de fine
crossing
s i gns . )
Note.
a ^( L )
ca n be n o n z e r o
on a 3 - c o m p o n e n t
link: i s an
From now and
on,
link d i a g r a m s .
we a s s u m e
a(K)
is w e l l - d e f i n e d
examp 1 e .
on knot
CHAPTER
PROPOSITION d ia g r a m . (i)
3.12.
be an o r i e n t e d knot
is
invariant
links
If
K,
K
under L
and
the R e i d e m e i s t e r are
K
are
consistent
Th e
idea:
the c r o s s i n g s
p ar t
of
the
T hi s
moves.
a (K )- a (K ) =
lk(L).
L
satisfies
P roof. of
K
a(K)
axioms
link
r e l a t e d as
then
Thus
or
Then
a(K)
(ii)
K
Let
39
III
the a x i o m s and
ot(K)
Position i nv olved
switching
idea w o r k s
for
a^(K).
Hence
these
= a^( K ) .
the b a s e - p o i n t
so
that
in a g i v e n R e i d e m e i s t e r
"none" move
are
seque n ce . for m o v e s
of
type
1 an d
type
2 as
s h o w n below-'
Since the
a
is d e f i n e d
R-move
for
each
by a sum of
i nv a r i a n t s ,
we
form
sum w i t h o u t
changing
in
the
va lues. Th i s
idea a l m o s t
works
for
the
type
3 move:
can p e r f o r m the
CHAPTER
40
The
starred
switching above.) term
a
switched do
(*)
sequ e n c e . However,
or
in a n y
every
change
( Hence
this
it ma y And
equivalence,
by
may
or
a(K).
if
two
case,
term
be
still
the
spliced. spliced,
type
an y
proves
"none"
starred If
we want
looking
inv a r i a n c e .
m ay
be
we
can
at
a
still
simple
in
to do a nd
the
In a g i v e n
crossing
as
in
in q u o t e s
s w i tched,
we are
a ^ 1k (E ^ S ^ ^ •••S ^ K ) This
involved
no p r o b l e m !
two m o v e s
mo v e
be
we h a v e
presents
1k (E S _ ^ •••S ^ K ),
the move.
Thus
crossing
III
can be
hence
inherited
will
not
CHAPTER
Part
(ii)
Position
Hint:
the proof,
Exercise
will
the b a s e - p o i n t
(A small
osition 3.10-3.13)
-
s i gn
(This
so
it
Rewrite
inductively
Investigate
bx a
is a
See
+
[J01],
c as e
the
This
the
defines
of
consequences
the C o n w a y
s ig n !
t opo logical
is a s p e c i a l
n omia l .
3.13.
correctly!
project).
in A x i o m 3 for
(v^-Vjj- = zv^) polynomial
Exercise
completes
theory all
of
(Prop the
coefficients.
E x e r c i se 3 . 1 4 . the
left as
41
h
3.13
polynomial
be
III
Prove
invariant the
o f rep lac ing
Polynomial
that
the
resulting
of k n o t s
and
f irst g e n e r a l i z e d
[J 0 2 ] , [J03]
and
[ H O M F L Y ] .)
links.
poly
IV EXAMPLES
Here 3. N o t e of
th e
and
we
continue
that
the
consistency
then
some
E x e r c i se
4. 1.
These
are
of
skein
v
For
z =
1,
Here
Fibonacci
n
with
= v T, K n
this
Chapter
the
knots
then
yields
component
THEORY
via
3 has
axioms.
theory
shows
SKEIN
calculating of
alternately
If
(along
end
AND
the
provided
First
(see
Conway
and
l i nk s.
axioms
some
that
Fibonacci
none
count
for
42
of
a proof recursions,
Thus
Series
these
the
Chapter
[Cl]).
v -v 0 = zv 1. n n-2 n-1
the
of
are
first
we
have
1,1,2,3,5,•••. equivalent
tw o).
CHAPTER
V1
V2 V3 v4 V5
V6
L
IV
43
44
CHAPTER
Thus
v K = V £ = ( 1 + z 2 )2 .
receive T he
the
proof
inequivalence
have
developed
c op y
of
to
the
this
show
so
far.
tr ef o il
example
that
(Why?)
same p o l y n o m i a l ,
of
K
later
and
K
ar e
K
not
subtler
that
K
image.
(Ex e rc i se :
Us e
and
K
equivalent.
methods
than we
is c o m p o s e d We
shall
Exercise
of a
return 3.15
to
inequivalent!)
4.2.
Find another
distinct
knots
that
wh ere
also
its m i r r o r
on.
knots
they ar e
requires
Exercise
P r o b 1e m :
The
but
No t e
and
IV
s h ar e
example
the
of a pa i r
of a p p a r e n t l y
same p o l y n o m i a l .
Given a polynomial
f(z),
fR e s e a r c h
investigate
K(f)
K ( f ) = ( K | v R = f }.]
SKEIN NOTATION When in
the
links
A,
B
an d
C
are
we
shall
©
and
C
write
0
A = B © C
v.
for
switching
ABC
an d
C
B = A 0 C.
a r e n o n a s s o c i a t i v e , an d
notation
as a
B
these
operator
= v.-z v ~. A C
T hu s
in
this
operations a conven
[You m a y
t h i nk
of
form.]
v^ _vb = ZVC ‘ we
T he
they p r o v i d e
relationships.
By Axi om 3 we h a v e an d
related
form
A
ient
diagrammatically
could also
Hence define
vg0c = VB+ ZVC ©
and
0
45
CHAPTER IV in
Z[z]
tion, VA®B
and
by
f © g = f+zg
the
related
and
f 0 g = f-zg.
ideas a re
due
shall
venience. Theory
use
©
However,
as
B ~ B7
0
Conway
foll o ws :
and
an d
creates
Define
C ~ C'
primarily
Then
where
A', B7
fit t o g e t h e r
as above.
this
w a y we a l l o w
the p o s s i b i l i t y
m o r e than with
one
B 77
way!
and
compositions cally
C 77
to
B 7 ~ B 77 , skein
ate d ) .
and
Th u s
B7 © C7 C 7 ~ C 77 .
equivalence
fitting
be
say
if
these
the
C7
that
A ~ A 7,
are
we m a y
B 77
diagrams
compositions B 77 © C 77 -
this
in in
C 77 ~ C
T he
B 77 © C 77
equivalence
do
~ B,
m a y not
con
Skein
whenever
together.
that
We w r i t e
calls
including equivalence
B7 © C7
we
he
and
there ma y be
also
B 77 © C"
equivalent.
e q u i v a 1ent
Thus
By
for n o t a t i o n a l
w ha t
A = B © C
that
let
to J o h n C o n wa y .
nota
= V A ® V B'
We
and
This
resulting
be
topologi
is a re
ske in defined
B7 © C7
relation
(and
so g e n e r
CHAPTER
46
More ©
and
are
generally,
9
ar e
topologically /.
Thus
(topological v
skein
links
Open
P r o b 1e m :
not
Is
just
a
f an c y
way
of
the
skein
n
components.
d e c o m p o s i t i on
classes
of
to
of An y
ab ove
then
equivalence
f r om
skein
the
links,
then
C#/sk
to
: % / s k — > Z[z].
skein-equivalent
knots
or
equivalent.
we ha d
Th i s of
the
saying out
knot
K = U 0
is a
skein
that,
on one
0 0
K
in
$
of
kn o t
a nd or
that
the
U^'s.
where
s k e i n - d e c o m p o s i tion
recursion, the
1 ist:
These
are
links.
link
(L © U)
A nd
& = '&/sk.
by
,•••.
knots
involving
L'
and
v
terms
the u n k n o t ?
00 of
of
L
of k n o t s
9).
two
involving
individual if
set
there a n o n t r i v i a l
,o if
©,
topologically
bottom
, 0 0
the
homomorphism
the g e n e r a t o r s
calculations
u = 0
L =
if
Clearly,
denotes
example
example
and into
their
(operations
skein-equivalent
U =
equivalent
%
F i n d an
the
compositions
equivalence)
that ar e
In
K
if
Z[z]
Exerc is e •
two a l g e b r a i c
equivalent.
is a w e l l - d e f i n e d
the
is
skein
IV
Let
all
of
this of
is
our
the g e n e r a t o r s =
00
can be w r i t t e n as
a
•••
0
s ke i n -
CHAPTER
IV
47
Example:
E = V
© L,
L = U2 0 U 1
E = Ul ©
(U2 0 U x )
t
v r = 1-z E E Note
that
we
have
We will simple
by
recall
that
denoted
is
now
the
sta t e
existence
Thu s
to
a
This
of
the sum
is d e f i n e d may
it
of
it
from
depend
skein of
by
this
the
is m a d e
decompositions. K
splicing
upon
trefoil.
proof
links
the
a nd two
choice
way:
very First
K 7,
strands of
K # K'
K' think
knot.
theorem whose
the c o n n e c ted
K I prefer
figure-eight
distinguished
K # K 7,
s h o w n below.
the
2
as
strands.
CHAPTER
48
THEOREM
4.3. V K#K'
(ii)
= V K V K'
K is
If
K,
Let
the
on all
K7
be
oriented knots
( p r o du c t
res u lt
strands
of
of
IV
in
links.
Z[z]).
reversing
K,
or
all
v
then
=
K
orientations
.
K
I
(iii)
Let
K*
by v
be
switching I ( z )
=
K ‘
(iv)
If
L
v k K
=
every
image
crossing
K
of
of
K).
(obtained Then
( “ z ) ■
is a
? L (-z)
lin k w i t h A
(-l)X+ 1^ L ( z ) •
components Hence
v
then , = (-1)X + 1 ?L .
E x e r c i se 4 . 3 .
Proof :
COROLLARY ponents, are
the m i r r o r
not
4.4.
If ^
and
L 0,
is a then
link w i t h an L
and
even number
its m i r r o r
i mage
equivalent.
E x a m p Ie :
L These
links
are
not
e q ui v a l e n t .
•
of
com-
i L"
CHAPTER
We
N ote:
have
(one
already
strand
shown
has
49
IV
that
orientation
reversed
fr o m
L)
No w
(figure
e ig h t
knot )
- V L +Z = z ( 1 - z ^ ) = z the v e r t i c a l
dotted
also! a xis.]
[This We
follows therefore
by
symmetry
have
the
around
following
tab 1e :
with any
component
o r i e n t a t i o n has
v = +z"
wit h any
component
orientation
v = -z
has
.
Therefore
the
50
CHAPTER
u n o r i e n t ed
Whi t e he a d
1 ink
W
IV
and
her
mirror
image
W'
inequivalent.
w
Example
U.5.
W e a v i ng
X, = RX. X,= R X
This
is
a
generates
simple the
chain
weave
is
stitch. of A
the
The
basic
form RA
recursion
that
are
Thus
X
. = RX . n+1 n
From
51
CHAPTER
IV
this
can c a l c u l a t e
RA
we
v
=
n
X
• n
RA
Splicing:
-zv.
LA LA
Thus X
v„A
=
RA
-z^VA. A
Vt
A
In our
case,
X
= R n X ri = R ( R n _ 1 X~) ~ R n - 1 X n 0 v 0J 0
n
is,
if yo u
becomes
switch
the
unknotted.
=
crossing
1-z
=
V^
= 11-z
V0
=
2
,
2
2 4J
You may
Vv
00
Then = X
00
X
,
then
it
n-1
.
2
6
4
be
t e m p t e d by
-z
would
In p l a c e .
6
V
2
there
= 1-z v Y
.
-z 4
1-z + Z + Z 1
RX
of
Tha t
1+Z2
= 1-z + z -z
ity! J
Hence
2
n V0
R n X~ . 0
R X 7 - X T ~ 0. 0 0
right-most
.'.
=
n
of
Whence
n
2
,
4
1-z + z - • • • ± z
=
2n + 2
8
this
be an X
’’i n f i n i t e =
n
(1+z
formalism
2
knot”
2
1-z V v , X n-1 )vY
=
1
to go
an d
to
X 00 .
we w o u l d
infin And h av e
52
CHAPTER
IV
1 2 a. = 1-z + z4
1+ z This
formal power
+ ** *± z^ n + ^. knot
X^??
But
series
is indeed
is there
the
limit of
such an entity as
One possibility
for
= 1-z
this
infinite
is a wild knot
form
2
in the
______
P The
Here such
’’wild point"
represents a homeomorphic that
hood of
the image has a wild point p
contains
the pair
(ball,
arc)
s tab i 1i tJ y:
3 IR
in
Every n e i g h b o r
Neighborhood (T K )
Nevertheless,
there
is a sense
in
from
K
and
does not
does have
the weaving
You can do any
K 00 ’,
then
finite amount
making him disappear.
3
in an unknot! K 00
In this case
3
— » IR
If you call
is a curious animal.
there
is an infinite
corresponding
that unknots
considerations
the
of unravelling of him without
composition of elementary moves : IR
in which switching
results
switched version
topological
1
RK CO = K 00 .
starred crossing
h
p.
S
(under a h o m e o m o r p h i s m ) to the standard
pair.
However,
morphism
image of
infinitely many crossings
(Neighborhood,
straighten out
this
p.
--
K
.
to a homeo-
In general,
for wild knots are more
the
CHAPTER
complicated. differently
with
Instead, as
in
infinitely
three
dots.
X 00
construe
the
infinite
knot
below:
many
But
we may
53
IV
tiei n g s
this
beast
in
the
doesn't
region live
indicated
by
the
in E u c l i d e a n
space! I suggest represented as
X^
the
by a p i c t u r e
= [X Q I X
quences
of
following
a s tab 1e equ iv a 1ence [a]
= [b]
if
some
k ,H .
then
RX 00 = X 00 . We
als.
Then
can use
knots
where
we
the
same
that
of
of
above; of
as de f ine
infinite
[ sLq ,3.^ , • • •] = [a]
infiniten-tuples.
= b n+a for all
if
n
stable
classes
se
denotes T h a t is,
= 0,1,2,***
set R [ a Q , a ^ , * * * ]
X^
an d
= [ a ^ ,R a ^ ,R a ^ ,•••]
for
the p o l y n o m i
Thus VX
00
= [V X 'VX ’V X '* ’ *] Ao 1 2 =
a nd
to
Think
in a c a t e g o r y
cla s s
a n+k
out.
similar
fX 2 ,X3 ,•••]
ordinary
way
this
can be
r,, [1 + z
2
,
1,—Z2
4
- Z
, • • • ]
taken as a r e p r e s e n t a t i v e
,
of
the
formal
54
CHAPTER
power
stable
v.
00
(See
1 + z -z + ••*.
series Other
IV
infinite
sequences.
knots Thus
have
v ’s
that
only
exist
as
if
= [ 1 , - z ,z ^ ,- z ^ ,•••].
then
You m ight
say
vA
= (-1)°^° CO
[ K 3 ] .)
E x e r c i se 4 . 5 . weaves
Choose
and knots
Rema rk .
property sequence sequence
=
that
recursion
defined
R
on
the n
an d
sequences
( a ^ ,R a g ,R a ^ ,R a g , • • • ) .
lim R n-*» is
own
analyze
the
so ob t a i n e d .
We h a v e
R ( a Q , a j , •• •)
your
limit
(a)
of
R n (a)
= (a^.RaQ.R
invariant
under
R!
2
by
Th i s
makes
has
sense
3
a ^ ,R a ^ ,•••) Then
taking
the ni c e as and
the this
CHAPTER
stable
equivalence
(a 0 ,Ra 0 ,R 2 a o ’*'*) ~
classes
way
[a]
has the
( R a 0 ,R2 a 0 ,-.-)
~
k k+ 1 (R a ^ ,R a ^ ,•••),•••.
is a formal
55
IV
”R a^
that
~ (R 2 a 0 ,R3 a Q ,-- ) ~
In ot h e r
to say
effect
2
words
for
k
•••
[ a Q . R a ^ . R a^ , • • • ]
indefinitely
large.”
00
T hu s
R a^
is a g o o d n a m e
for
the
seq uence
[ a 0 ,Ra 0 ,R 2 a 0 , •••].
We
Re ma r k. Kw
could
denote
question
have
with
is,
what
o nl y
Generalize
with
Digression recording nected
some
k .6 .
That
4.6.
Let
then
proof
*
the C o n w a y
(say u s i n g
w e ’re
that is,
K K
~ 0 => K ~ 0
The
labelled
Reidemeister
While
a proof
unknotted,
the w i l d
knot
K^.
Let
s w it c h e d .
The
polynomial
equivalences
moves,
or
into
that
infinitely
an
use many
co n t r o l ) .
sum.
THEOREM
K # K'
many
with
V Koo^
for w i l d k n o t s
finitely
moves
crossing
is
Re search Problem. invariant
stayed
w ill
yo u
talking wild knots
and a nd
take
Ky
con
to p r o v e
K ' be two kn ot s . are
form
If
K # K'
e a c h u n k n o t t e d . That
K ' ~ 0.
the
is w o r t h
c a n ’t c a n c e 1 k no t s u n d e r
we w i s h
a nd
it
of a d e tour:
is,
is
56
CHAPTER
Wild
Tame
Knots
So we h a v e
to
IV
Kno t s
— — — — — — — — — — — —
say
something
about
the
Tame
Knots
relationship
of
these
categori e s . A
(possibly
morphism kn o t s
a
a,p
orientation that
throws
1
3 — » S
of
— > S
3
we
preserving
words,
one
is
represented
the c i r c l e say
that
by an y
into
S if
a = p
homeomorphism
h
: S
3
3
.
homeoGiven
there — > S
two
is an
3
such
knot
h(a(S*)) to
= p(S^).
the oth e r
and
The
homeomorphism
transforms
the
h
surrounding
as we 11. One
without knot
: S
1
knot
p = h o a.
In o t h e r
spa c e
: S
wild)
says any
that,
standard
that a kn o t
wild up
points.
is
tame
Th u s
if
it mu s t
to h o m e o m o r p h i s m , looks
(ball,
arc)
pair.
it
is be
=
to a k n o t
equivalent
locally
like
to a
the
CHAPTER
IV
57
Standard
Pair
3
Fact:
Let
grams
K
T ha t the
is,
K,K' an d
K '.
for a d e t a i l e d
territory
Proof
of
be a Then
equivalence
topological
This
C S
fact and
equivalence discussion allows
return
T h e n we ma y
Cfl
us
=
of
moves
defined
this
only
if
is
by
K ~ K'.
the
above.
dia
same
See
as
[Rl]
point.
to v e n t u r e
out
into
the w i l d
safely!
Suppose
indicated
write
if a n d
K = K'
via Reidemeister
the T h e o r e m .
w i l d kn o t
tame kno t r e p r e s e n t e d
that
K # K'
# K # K'
#
= (KUK')
(K#K') #
•••
3 ( ^ 0 -
Form
below:
% = K U K'
ar = C )
~ 0.
#
# O
# 0
•••.
# •••
Hence
the
CHAPTER IV
58 On
the o t h e r
hand,
* = K #
(K'#K)
#
(K'#K)
#
•••
* = !(##•••=:# .*. Hence,
by F a c t .
Re ma r k.
This
an d
ar e
Nn
~ K.
sam e
Mn # Nn = Sn
(remove resulting
and
as Let
the
R
is c o n n e c t e d
Find a too
is
Mn
£
then
denotes
for m a n i f o l d s
together
along
the
idea of g o i n g
off
live w o r k s
of
formula
R s u ch
for
into
in some
place
other
r i ng w i t h u n i t
that
(1-ab)
some
^
1-ba
r e a lm s 1.
is in v e r t i b l e .
thereby showing
i nv e rt i b l e .
Solution:
(1-ab) ^ = -r~~— tt v J 1-ab = 1 + ab + a b a b
+ ababab
=1 + a ( l + b a + b a b a + • • • )b .'.
Exe r c i s e .
if
manifolds,
where
sum
be a n o n c o m m u tat ive
a , b be e l e m e n t s
it
Nn S Sn
that
■
boundaries).
Let
P ro blem: that
#
the proof.
to s h ow
n-dimensional
and
" i l l e g i t i m a t e ” limits
well.
completes
f ro m e a c h a n d p a s t e
Furthermore, where
closed
Mn = Sn
n-balls
This
i de a c a n be u s e d
compact
homeomorphism,
X = K.
Show
(1-ab)
that
this
* = 1 + a(l-ba)
formula
r eally
*b.
works.
+•••
CHAPTER
Example
k .7.
A
Thus
B
A
and
Example
k.8:
available to
tang le and
T hu s
A'
are
T a n g 1e T h e o r y .
[Kl],
is w o r t h w h i l e theory.
"outputs"
C
skein-equivalent.
for p o l y n o m i a l
[ G l ] , [Cl], It
59
IV
A in
[K2]
There
calculation. and
[LM]
form:
many We
the
diagram
more
r e f er
for m o r e
to e x p l a i n he r e
tang 1e is a k not this
ar e
tricks
the
re a d e r
information.
elements with
of
"inputs"
CHAPTER
60
is a s i m p l e connected
tangle.
Assuming
in w i t h a
larg er
IV
that
k not
the
t an g l e
d i a gr a m,
yo u
is a c t u a l l y ca n d e c o m p o s e
i t ske in-wi se .
Here
we
t a ng l es
have
that
above
Clearly, »8=2 ’ * * * cates
T = £1 ©
Q.
and
the
skein
a n d by
the p r e s e n c e
unlinked Now
Thus
circles we
®
for of
of
many
the
we
reasons
tangl e s
= -= ^ '=2 1 * * *
in
define
where
(n
have
called
about
to be
is g e n e r a t e d where
for
the
0^)
the
two
re v ea l ed .
by
subscript
indi
unknotted,
ta ngle box.
addition
of
t an g le s
in
the
obvious
way:
0 +
“ + “ =
F in a l l y ,
we
1 inks
tang 1e s :
to
define
^ two
=I^> & operations
that
C !l = ® j .
associate
knots
and
CHAPTER
IV
61
This
is d e n o t e d
N(A),
and
called
the n u m e r a t o r
This
is d e n o t e d
D(A),
a nd
called
the d e n o m i n a t o r
We a l s o of
A,
define
F(A),
by
a quotient
o f p o 1y n o m i a l s
of
the
A.
of
A.
f rac t i on
the
F( A) = v NA/ v DA. Thus,
the n u m e r a t o r
tang le
ar e
and
the C o n w a y
denominator
of
THEOREM
( C on way).
4.9
you
polynomials
the
The
Example:
the
fraction
fractions:
the
fraction
the n u m e r a t o r
of a sum
of
the
an d
= V N A V D B + V D A V NB
VD(A+B)
= VDAVD B ’
fraction
0 + ® =
is
the
Explicitly,
VN(A+B)
— + — = xw+yz y w yw
like,
of
of
A.
(f o r m a l ) sum of
N ote:
denominator
formal sum of fr a c t i o n s . ------- --- — -----------
x
—
»
is an
ordered
pai r
[x,y ]. )
fIf v
62
CHAPTER V CD
IV
A
= Vf- = T FJ.) - I S = I
Example:
0
1
1
0
(-)
I 0
A little
Thus,
1- 0
" 0
®
f
Conway's
0-0+1-1 _ 1_
_
= £.
I
+ 0
theorem for
its proof
1*0+0*1 _ o 0*0 “ 0*
“
thought
F (“ i) = §
shows
that
it is sufficient
to check
the skein generators as we have done!
is easy.
But
it is a powerful
tool
for
c a 1c u 1a t io n .
Note: since
T =
^ = -3z,
should be called
= 1.
Call
So
r ( |_n J ) = nz/1, But now
M L nJ
) = 1/nz.
this
[2]"
[~3]
CHAPTER
63
IV
1 _ 3z^ 2z 1
F (A ) = F ( w V F ( r - c ) =
1 -6 z 2z
2
A v
v
Thus
we
conclude
that
In g e n e r a l ,
the
quickly
calculate
inators
of
tan gl e t an g l e s
[n]
i n v e rs i on ,
K = NA
fraction
tang 1 es
by a d d i t i o n
(n € Z ) .
n a m el y ,
2z .
DA
polynomials
rational
obtained
if
1-6 z 2
NA
theorem of
We h a v e
allows
the n u m e r a t o r s
where and
(4.9)
a rational
inver s i on already
and
the
one
In g e n e r a l ,
is a
i nt e g r a l
example
[n]
-i [i]
to
denom
t a n gl e
fro m
s ee n
us
[i]
of
CHAPTER
64
Note the
that
A
i n p u ts
^
and
is o b t a i n e d o utputs)
upper-left/lower-right
N o w we h a v e
that
FCA"1) =
1/ F (A ) .
For
example
see
we
A
rotating
(up A
to by
isotopy 180
o
that
fixing
around
the
diagonal.
*)
ca n
= D(A)
for m
and
continued
D (A
^ ) = N(A).
f ra c t i o n s .
z^ + 2z
T hus
We
N(A
by
f rom
IV
Hence
CHAPTER
IV
65
-+1
since
this
is
the
numerator
■
Exercise. Let --------------
C
[
of
1]
+
= N n
F ([1]+1/[1]).
i
And
---------------------- •
[ 11 + -------- :— L J 1 • • • -f---- -
with
n
[i]
appearances and
links
of
[1].
Show
are defined
that
~ K n +i
in Example 4.1.
where
the knots
66
Just
CHAPTER
as
fraction
the
snail
knots
builds
spiral
his
IV
shell,
ou t wa r d s ,
so do
these
continued
Rational lens
spaces O ne
e qual yet
to
([ST],
more 1.
(unless
knots
an d [SI])
e x a m p le . K
CHAPTER
IV
t a ng l e s
a re
as
you've
do n e
important
branched
A knot
is a c t u a l l y
67
K
whose
knotted,
Exercise
covering
but
in s t u d y i n g spaces.
polynomial we
can't
3.1 5 !)
K K = N (A +B + C)
F(A)
= 1/z,
F(B)
= 3z/l,
F(C)
= -3z/l
is prove
it
68
CHAPTER
You
should
N ot e
that
Hence
this
F (A +B+C) • •
Remark: foil
check
that
is
the
= F(A)
V N (A + B + C )
The
knot.
Exerc i s e .
l in k i n g
number
of
=
the
two
curves.
+ F(B)
+ F(C)
1/z,
of
is c a l l e d a cab 1e of
=
numerator K
IV
i tself
C
is an u n t w i s ted d o u b 1e of
the
out
of
(a)
Work
Exerci s e .
Take
a k n ot
cable
reverse
the
t h e or y
of
t an g l e s
the
tre
trefoil
the
form
Research
with
orientation.
"
>C
Form
the
CHAPTER
Prove
that
eas y p r o o f proof.]
= later.
lk(K)z. There
[In
IV
this
69
p ro b l e m ,
s h o u 1d be a g o o d
we
shall
see an
skein-theoretic
V DETECTING SLICES AND R I B B O N S — A FIRST PASS
Here
It a
is a r ib b o n
is c a l l e d
a r ib b o n knot
" r i b b o n ” that
with
The
ribbon
ribbon,
pin g the
a form
image
kno t :
is
because
immersed
into
it
forms
the b o u n d a r y
three-dimensional
of
space
singularities:
or
2 : D— » IR
ribbon 3 C S
illustrated
singular
set
disk, 3
whose
above.
consists
is
the
image
a(D
)
onl y
singularities
Thus
each
in a pai r
70
component of
closed
of a ma p are of
of the
intervals
CHAPTER V
in
D
2
*•
one w i t h
end p o i n t s
i nt erior
to
entirely
D
2
on
71
the b o u n d a r y
of
D
2
,
one
.
3 Exercise. clasp
Show
that
every knot
K C S
bounds
singularities.
A clasp
But Th e
not
f irst
we k n o w form?
every
disk
that Read
it
to be in
T ~ 0
is not not
(5.2),
in
the
and
tec hniques
refe r
the
ribbon.
trefoil.
T is
2).
exercise
is not
T
two p a s s -e q u i v a I e n t
exercise
3.
reader
the
polynomial.
5.6.
knots.
of S e c t i o n
the p r o o f
Then
a(T)
=
1
pass-equivalent
T-equivalent we are
done.
to ^
while to 0.
0
78
CHAPTER V
It the
remains
trefoil
to b r i n g
or
to to
in m o r e
PROPOSITION connected oriented
show
the u nknot. geometry.
5.8.
Any
oriented boundary
Proof.
We
Seifert
[S].
Seifert
surf ac e
SEIFERT'S
that a ny
produce
K
is
T-equivalent
In o r d e r
to do
this,
we
to ne e d
In p a r t i c u l a r ,
oriented
knot
3
F C [R
surface
or
K
link
s uch
bounds F
that
a
has
K.
the
surface
Accordingly, (when
ALGORITHM
1.
D raw
the p l a n a r
2.
Draw
the
it
the
by an a l g o r i t h m
due
surface
called
is p r o d u c e d
will
by
this
(illustrated). diagram
corresponding
for y ou r
universe
knot.
k.
be
to H. the
algorithm).
CHAPTER 3.
Split
every
crossing
of
79
V
k
in o r i e n t e d
fashion:
V The
resulting
the S e i f e r t 4
.
5.
set
circles
Attach
a disjoint
to
Seifert
the
Between
of
disjoint for
i s the
of
One
disks
disk per
split-points
add
according surf ace
O r i e n t a b i 1 ity if y o u
curves
is c a l l e d
above
the p l a n e
K.
collection
circles.
closed
to
the
circle.
twisted
crossing
in
bands K.
This
F.
follows
That
is,
start
pass
through a number
from
in a g i v e n of
t he J o r d a n domain
crossings
in
in
curve
theorem.
the p l a n e
the S e i f e r t
and
surface
80
CHAPTER V
o nl y
to r e t u r n
even number surf a c e
diagram
surface by
traversing
to a v o i d
disks
ca n be
crossing
disk
draw.
y o u m us t
This
pass
geometry
t h r o u g h an
passes
over
to
the
may
sketched
Seifert
directly
circ l es :
on
the k n o t
jump at
each
cross
it!
Circles
be n e s t e d
K The
d o main,
crossings.
Se i fert
The
that
itse lf .
T he
ing
of
to
as
in
k
corresponding
to
Se ifert
this
"fringe"
Circles
is not
so ea s y
to
CHAPTER V Exercise. the
D ra w a g ood p ict ure
figure-eight
kn o t
for
orientable
to recall surfaces
For a s i n g l e b o u n d a r y is a c o m p l e t e surf a c e s . the
list
(See
the S e i f e r t
su rface
the c a n o n i c a l
(abstract
c om p o n e n t ,
E a c h of
representatives):
(F q , , • • • } ,
of h o m e o m o r p h i s m
[MA].)
representa
types
these
of
Fq
= D
2
,
orientable
representatives
takes
f orm of a d i s k w i t h a t t a c h e d bands. Up
to a m b i e n t
i so t o p y . an e m b e d d i n g
of
F
looks
S
a s t a n d a r d 1v e m b e d d e d di sk wi th twi s t e d . k n o t ted a n d bands. fits
for
(above).
N o w we a l s o n e e d tives
of
81
(That
into a
embeddings F (1) C IR
is,
gi ve n any
time-parameter F {t)
meets
such
that
3
embedding f a m i l y of F C IR^
F C IR
is
the d e s c r i p t i o n a b o v e . )
F(0) For
1 inked
the n
continuously C IR3
1 ike
F
changing an d
e xample:
CHAPTER V
82
Here
we h a v e an e m b e d d i n g as d i s k - w i t h - b a n d s
is a
trefoil
Exerc is e . ambient
Now bands of
Show
that
i sotopic
the S e i f e r t
to
l e t ’s call
t wists per b a n d
(Compare Exercise
F
surface
for
the
trefoil
is
above.
a disk with
twisted,
Since
(o r i e n t a b i 1 i t y ),
k no t t e d ,
t here
lin k ed
is a n e v e n n u m b e r
t hese
can be a r r a n g e d
2.7.)
the b o u n d a r y ,
a pass-move:
boundary
knot.
a standard e m b e d d i n g .
On
wh ose
e a c h curl
affords
the o p p o r t u n i t y
for
83
CHAPTER V
T hi s
means
m o d u 1o
two
Since an d
linking
k no t the
bounds
that
we_ can
reduce
it
is o b v i o u s
of b a n d s a
that
we
rid
by pa s s i n g ,
surface
that
cu r l s
per
ba n d
Hence
we h a v e
LEMMA
5.9.
can get we
of k n o t t i n g
can a s s u m e
is a b o u n d a r y
that
connected
our sum
of
cu l p r i t s :
trefoil
Any
of
by b a n d - p a s s i n g .
following
foils.
the n u m b e r
unkno t shown:
Any
knot
knot
is p as s - e q u i v a l e n t
is p a s s -e q u i v a l e n t
to a sum
of
tre
to
its m i r r o r
image
all
the band s!
^
(K ? K !).
P r o of :
Th e
To
see
the
c o u p de
PROPOSITION
5.10.
last
gr a c e
part,
p a ss
is:
For an y
knot
K,
K # K!
is a r i b b o n
CHAPTER V
84
Proof :
Connect ribbon
Proof s ho w is
corresponding surface
true
across
the m i r r or ,
and
the
appears.
of T h e o r e m that
points
5.3;
K # K ^ 0
in g e n e r a l
By
the d i s c u s s i o n ,
when
s in c e
K
is a
K j K'
it
suffices
trefoil.
to
In fact,
this
i m p l ie s
K # K ~ K # K ‘ - 0 s in c e
ribbon
COROLLARY
implies
5.11.
Two
( T -e q u i v a l e n t ) if a n d w here
Remark: ca n be A RF(K ) ,
a(K)
We
implies
K,
knots, o nl y
if
£ 0.
K', a(K)
|
are
pass-equivalent
= a(K')
(modulo
2)
= a^(K).
shall
identified of
j: 0
later
see
w i t h w ha t
the k n o t
K.
that
a ( K)
is c a l l e d
a(K)
tak e n m o d u l o the
is e a s i l y
Arf
two
i n v ar i an t ,
calculated
using
CHAPTER V
the
techniques
culated
a(K)
As a result,
Exerc is e . is a 3 - 4
It a
= 1
for
we k n o w
Show torus
is c a l l e d
a
that
III.
Thus
in E x a m p l e
3.8,
we
cal
K.
that
the
this k n o t
is not
f o l l o w i n g k no t
ribbon.
is not
ribbon
(this
knot).
torus
k no t
because
it
lies
on
the
surface
of
torus.
Remarks
on S l i c e
s l i ce
(in
s l i ce
knots
be
of C h a p t e r
85
the
fact, that
Knots. r i bb o n) are
not
s t e v e d o r e 1s kno t :
We h a v e
s een
for a n y k n ot of
this
form.
i K # K'
that K.
There For
are
ex a mp l e,
is many let
K
86
One
CHAPTER V
can
see a m o v e
K
K
o t h er
shows
Take
d i s k as
b efore
a disk with
you
one
way
two u n l i n k e d
a bit.
knotted
slice
follows:
just
sadd1 e
bounds
T hi s knots:
the
just
s tevedore
Hence
for
it be,
Go
singularities
to c r e a t e
c ir cles.
th r o u g h a s ad d le
then
after
sa d d l e
u n 1 in k e d
'tis a slice
volleys
Wrap to
knot
in
the
of
form
s lice
them a r o u n d
form a knot. for
1 i nk
sure.
If
e ach
87
CHAPTER V
E x a m p 1e :
E x e r c i se 5 . 1 2 . it has
Prove
a movie
with
that
a k no t
is
saddle
p oints
an d
ribbon
if a n d
mini m a,
but
o nl y
if
no
m a x im a .
Exer c i se 5 . 1 3 . (not
Prove
a connected
THE KNOT Two cordan t
CONCORDANCE knots
K,
(K ~ K') F :S 1
ding
unkno t . ponent
is
3
K'
C S
if
there x
I
represents an y
Just
the m o v i e
left!
Knot
is p r i m e
kn ot s ).
GR OUP
ex a mp l e, run
the S t e v e d o r e ' s
two n o n t r i v i a l
such that
an d F |S ^ x 1 For
of
I — ♦S 3
x
uni t i n t e r v a l ) K,
sum
that
s lice
are
said
exists
to be
a differentiable
( I ={ t € IR
1
F|S
x
(smoothly)
| 0
= F ( ^ , )
- F ( ^ » )
Ff
) (drop m u l t i p l e
- F(
ed ges)
= F(. N ) - F(*v^) - F( ^ ) 4*12
- 12 - 12
24. Certainly, ula bear
a
these
f ami 1v re lat i o n s h i p
kno t no 1v n o m i a 1 s v i a dix
for a d i r e c t Wh a t
sibility planar
c a 1c u l a t ions
does of
map,
the
F(G)
w ith
the C o n w a y
relationship chromatic =0?
If
then we w o u l d
some
s mallest F (G - a) a nd the
t
r
Thus
a
of
same x n f-
the
in
G-a
color and
so
means
y
ar e
^
four-color
calculations (See
the J o n e s tell
for m of
the a p p e n
polynomial.)
us
about
the p o s
a n o n - f o u r - c o 1o r a b 1e
- F ( G /a )
Let's that
that
(formerly in e v e r y
was
chromatic
ha v e
G.
noncolorable
= F(G/a)
y
that
ed g e
our
formula G
the
iden t i t v .
with
0 = F ( G -a ) for
with
suppose F ( G -a )
the
the ends
coloring
f o r c e d , an d
G
? 0 ? F( G/ a ).
" exp osed" of
of
is a
a)
G-a
that
•
T =
is:
Then
vertices
always
(G-a)
d_o tyr an t s exi s t ?
x
re ceive
We will
_
CU
problem
two
that
say
is a
149
CHAPTER VI It After
is,
all,
ordinarily switch
in fact, if
T
good
is a
of
they m u s t
to o b t a i n a n e w Let's
try
tr y i n g
tyrant,
communicator
the c o l o r
q u en c es ,
very
x
and
to
then
start
eventually
and
to m a k e
a nontyrant,
such
Thus,
a
switching
(of
The
two
3 other
vertices.
colors for
y
x
as
if y o u
following y
If we
d o w n the c o n s e
as well,
#R___ #B #
s witch forced
eventually c an be a
mus
if
T
is
#R y
x's
red (R) to
to ch ange,
f lips
y
tyrant
in a v e r y
to
them
we 11:
about a
t be c o n n e c t e d
Otherwise
affecting
connected
among
y.
extra
tyrant:
thi n g we n o t i c e
is that
directly
and
an
tyrant.
to
B
B
R,
as well. limited
c ol o rs ) .
fir s t
without
x
switch
that a r e
graph
colors)
c o l or
but
B' s
the a b o v e
domain
is a l s o
a
co l o r i n g .
switch any
then
to c r e a t e
T
between
#R__ #B__#R____ #B__#R__ #B x # # Here's
try
to (for
y. x the
tyrant (for
d i r e c t l y toat
x
would
be
And
these
3
must same
a lways
free
reason).
three All
least
to c h a n g e
(or m o re )
have
four
vertices
different
this
is
true
CHAPTER VI
150
We
could
Suppose
x
try
to do
this as
is c o n n e c t e d
s i m p l y as p o s s i b l e .
to e x a c t l y
3 other
vertices:
1
If we ored
The
try
differently
second
f rom
x
We've
firs t
r es u l t bring
of
sin c e
ar e all
them we
there
co l o r
into
d o e s n ’t look
further
the map.
is d i s a s t r o u s
2 back
(1,2,3)
connecting
is out
possibility 2 fr o m
nether-reaches
the
these
mu s t
col
find:
ex i s t
a path
y.
dropped
change
that
by d i r e c t l y
possibility
to
Th e
we
to e n s u r e
at for
x
direct For
communication
with
the
exa m pl e :
without tyrants!
communication:
too p r o m i s i n g .
disturbing
1 or 3.
Of
we
course,
can
The try
to
151
CHAPTER VI
4
But
this
splits
the c o m m u n i c a t i o n b e t w e e n
1 and
3,
allowing
B R.
with
x
free
Perhaps ing a
begin
Proving
a dangerous is du e
technique
colors. to see that
game.
the d i f f i c u l t y
t y r an t s The
be s t
don't
exist
guarded
to H a k e n an d App el 1, u s i n g
in c o n s t r u c t is,
proof
much
at
of the
computer
[AH].
Exerc is e . below?
you
tyrant.
course, moment
to c h a n g e
Ho w m any
Sa y h e l l o
I sometimes
dream
substructure.
Ah
to
four
colorings
the n o n p l a n a r
of p r o v i n g s o . ..
ar e
there
for
the g r a p h
tyrant:
that a n y
tyrant
has
V
as a
152
CHAPTER VI
§17.
THE MOBIUS Th e
Mobius
BAND band
is
usually
represented
by
a
drawing
s uc h a s :
Si nce
the b o u n d a r y
research
problem
in
e m b e d d ings
of
For
a good
history
of
Here
follows
an
(her
the
ofthe b a n d
band
is u n k n o t t e d
it m a k e s
three-dimensional graphics with
s tandard1 v
this p r o b l e m , original
nice
to
f ind
u n k n o t ted b o u n d a r y .
see
solution
a
[S2]. by
Carmen
d r a w i n g s ):
U s u a 1 M o b iu s
Twi s t O v e r
Safont
CHAPTER VI
Straighten
1-2-3.
and b e g i n
153
to smooth.
somewhat
more
rounded
154
CHAPTER VI
piecewise Here
the
simplices
462,
417}
f orm
the b o u n d a r y .
fo r m
{156,
the M o b i u s
652,
257,
Band.
751,
Edges
linear
136, 14,
237, 24,
467,
23,
31
155
CHAPTER VI
Another computer tion of
possibility
to p r o d u c e the
= {(z^.Z g )
L.
Siebenmann,
representation
drawings
following
S3
for
of
the
embedding
| | z 1 |2 + |z2 |2 = D a n As i mo v ,
of
1}:
is
the u se
stereographic the M o b i u s
(This
has
projec
band
been
of a
in
done
by
the a u t h o r , . . . ) 7r
[ 0 , 2 tr] x
TT
2’ 2
M( 0 ,4>) = ( cos ( )e
i0 / 2
i0
L. S i e b e n m a n n & A s s o c i a t e s , 1984
§18.
THE GE NER AL IZE D POLYNOMIAL An
during t hese
extraordinary the S u m m e r
n otes
prepared). invariant
are
of
1984
based,
Vaughan of
breakthrough
and
Jones
oriented
(just
after
during [J01]
knots
a nd
occurred
the
in kn o t
the c o u r s e time
on w h i c h
they w e r e
discovered
a new
links
satisfied
that
t heory
being
polynomial a set
CHAPTER VI
156
of a x i o m s
as
follows:
AXIOMS 1.
To
each
s uc h
Vv = V „ , K K
whenever
that
=
" Co nway
t V
= (>Tt -
polynomial"!
stranger
into
of a n e w
than
via a cons tr uct ion
of
new polynomial many
images.
previously It Jones' end Ju ly
and
K'
are
whenever
K,
K
For
t heo rists
this
and
and has
it has
knot
He
in
the
sky.
obtained
representations algebras
a power
of
the
that no
from
simple
classical
u sed
mainly
Furthermore
ability
t re foil)
Jones'
polynomial
physics!
incredible the
his
previously
statistical the
An d
was
to d i s t i n their
mirror
invariant
had
assumed.
is b e y o n d
the
representation
there. of
new
kn o t s ( i n c l u d i n g
Thus
K
1/nTT)VL
star
that.
operator
in q u a n t u m m e c h a n i c s
guish
e Z[t,t
r e l a t e d as
the a p p e a r a n c e
this
is
1.
are
group
there
iso t op i c.
-
L
braid
K
link
polynomial
t
w o r k was
or
a Laurent
3.
like
POLYNOMIAL
associated
V
Another
JONES'
o r i e n t e d knot
ambient 2.
FOR
1984
Many
capability theory.
people
heard
(the p r e s e n t
of
these
Ho w e v e r , Jones'
a uthor
alas
notes
the
init i al not
to go
story
does
lectures
among
them)
into not in and
157
CHAPTER VI
a mong
these
a number
embracing both
saw c l e a r l y
the C o n w a y
g e n e r a 1 i zed p o 1v n o m i a l . dently Pe te r
by:
Ken Millet
Freyd
and
[ H O M F L Y] ) . tive of
Of
technique
David these
dently
Yette r , peop l e,
theory. by
was
Adrian Ocneanu all
Ocneanu
Joze f
forth
Lickorish,
did
or b r a i d
The
polynomials.
brought
Raymond
on d i a g r a m s
discovered
J o ne s
G^ ,
an d
F r e y d - Y e t t e r ) except
representation
an d
to a g e n e r a l i z a t i o n
their
H.
Ji m Hoste, (see
Przytycki
was
also
an d
by
(in
who g e n e r a l i z e d
polynomial
the
indepen
work
diagrams
Thus
induc
the
cas e
the b r a i d indepen
Pawel
Traczyk
[PR]. The
generalization
Conway Jones
(For and
yet
Question: the
as
(A)
vk
— ■ ->
(B)
t_ 1 V R - t V^- =
discussion
to
about
— .. >
another gen eralized
further
Appendix
comes
these
For
of
f ollows:
“ VK = ZVL
polynomial
the J on e s
[lT - ^ = ] V L •
du e to
polynomial,
see
the
notes.)
what
"arbitrary"
coefficients
re lat ion
a G „ + bG pr = K
K
the au t ho r ,
K
K
c Gt L
L
a,b,c
does
158
give
CHAPTER VI
an
invariant?
normalization
the
And
situation
AXIOMS 1.
To e a c h iated
i nc r e d i b l y ,
oriented
knot
a Laurent
K
K
and
or
by
After
the
POLYNOMIAL. link
polynomial
there
in
two
€ Z[a,a ^ z , z
are
does.
is a s s o c
variables
*]
a m b i e n t is o to p i c ,
then
= G K-
gk
2.
=
3.
expressed
FO R G E N E R A L I Z E D
G^( a,z) If
ca n be
it a l w a y s
aG
1.
^ - a
*G-y*
= zG—r . •------------------------------
Thus:
(i)
a= 1
(ii)
■ > G^ =
z = I— - - >fa
, = >
the C o n w a y
polynomial.
G^ = V ^ (a ) ,
the
J on e s
polynomial. Other
authors
z = -m
gives
What
different
ar e
many
in
o f kno 1 1 e d . t w i s t e d
bands
The new va riable
axioms
are:
20)
to a s k a b o u t
the ne x t
interpretation.
(by S e c t i o n
of L i c k o r i s h
questions
the g e n e r a l i zed p o 1 y n o m ia 1
shall
Thus
a = H
*,
a n d Mi l le t .
on h e r e ?
I take a ste p
geometric
lett e ri n g.
the p o l y n o m i a l
is g o i n g
There iants.
us e
What
two
these
sections
I s h ow
is
new
toward a
that a ver s i on o f
i s an a m b i en t iso topy in
th r ee - di me n s i o n a 1
measures construct
twisting a
invar
in v a r ian t
space.
of bands.
B-polynomial
Thus,
whose
we
CHAPTER VI
AXIOMS 1.
Let are
K,K'
FOR THE
159
B-POLYNOMIAL
be
oriented
links
(knotted)
oriented
t w i s t e d bands.
times
called
fr amed
ambient
isotopy
space.
Then
B^fa.z)
€ Z[a,a
of
whose
I i n k s .) bands
there
in
^
Let
^1
(Some denote
three-dimensional
is a L a u r e n t
*,z,z
components
such
polynomial
that
K
B v = B v/ K.
K.
K ^ K '.
whenever
aB = a _1B
Note form ing
that
the
exchange
(no n e w v a r i a b l e s ) . in
The
ide ntity
is
in s t a n d a r d
n e w var i a b 1e m e a s u r e s
twist-
the b a n d s .
By u s i n g lar
here
isotopy"
topological (see S e c t i o n
the c o n n e c t i o n
between
the
s cr i pt 18)
and
the
the n ext
concept
two
B-polynomial
of
sections
and
"regu draw
the g e n e r a l
ized p o l y n o m i a l . For sample
the
rest
of
B-polynomial
this
s e c t i o n we go
cal culations:
t h r o u g h a se r i e s
of
160
2.
CHAPTER VI
By
the a x i o m
B
3:
B
= zB
$ -i
@r
.
= B
Le t
S = (a-a
^ )/'■
BL = 6 BU =
= Bj- + z B y = 6 + a
(a - a
4.
* )z
W>
* + a
*z .
mm a B
bk
=
bk
bk
= “
“
bk
(1 -a It
is
ea s y
to
bk
_ zBL
)Bj^ = z Bl . see by
( 6 = (a-a 1 ) / z ) t
induction
where
that
L = A LIB
B^
= S B^ B g
is a spli t
link.
161
CHAPTER VI
R 1/
H en c e
K
—
Za
_a-a
i -1
If
-l] a ~ a
J[
z
R -tS »UR ti
J
A B
Bk = “ b a b b and
bk = “ ’ 1babb-
A similar gives
argument
the p r o d u c t
s hows of
that
a s traight
5.
B
B
n
n
= B„
= B
. i\ n
sum’
the p o l y n o m i a l s :
A*8
Let
"connected
Then
0 + zB n-2 n-1
B„ =6, u
B. = a, i
b a #b
-
baab
162
CHAPTER VI
1 (a-a 1 )
Bq
=6
= z
Bj
=a
= a
B^
= za + 6
= za + z *(a-a
2
2
B ^ = z a + z 6 + a B^
6.
= z^ a + z ^6 + 2 za + 6 =
It
follows
K
by
it
is u s e f u l
is not
This
link g o e s
equ al
to
for
Thus
B^(-a
the
by w a y
of
if
*) + z * ( a - a
i K*
is o b t a i n e d
then
B
i nvariant
we
see at
*)
from
f( a fz) K* under
a — *• -a
in
f o rm
the
on c e
*
of
that B ^ ( a , z )
*,z).
f l a vo r
t w i s t e d bands.
con nection with
)
the p o l y n o m i a l s
z,a,6 .
of
is
6
leave
should give
polynomial the
to
that
crossings,
Since
1
(2a - a
z^a + z ( 3 a - a
induction
*,z).
functions
e ate
by
r e v e r s i n g all
= B^(-a
-
= z a +
*)
of
calculating
Th e n e x t
the g e n e r a l i z e d
topological
script.
two
the
sections
polynomial. If we
denote
Bdelin The
163
CHAPTER VI
and
Consequently,
the
type
§19.
I
f
--
we a r e
ar e
led
to c o n s i d e r
> o ^ v > o
the
crossing
Define
the wr i t h e .
of all
of
its
isotop i c.
diagram moves
without
AND R EG U L A R
ISOTOPY
signs:
w(K) ,
crossing
ambient
replacemen t .
T HE G E N E R A L I Z E D P O L Y N O M I A L Recall
not
of a d i a g r a m
K
to be
the
sum
signs. w(K)
= I e(p) P
where
p Thus
writhe
runs the
of
+3
In g e n e r a l , switching
over
tref oi l and
a knot
all
all
the
-3,
and
crossings T
a nd
in
the d i a g r a m
its m i r r o r
image
K. I T*
have
respectively.
its m i r r o r
crossings)
h av e
image writhe
(obtained of
by
opposite
sign.
164
CHAPTER VI
If then
the w r i t h e
its
calculation
tinguishing re gular
mirror
is otopy
regularly a
were
in variant
of a m b i e n t
w o u l d be an e x c e l l e n t
images.
(denoted
isotopic
sequence
an
Writhe ~) .
if one
of R e i d e m e i s t e r
i_s^ an
Tw o
can be moves
method
obtained type
for
invariant
diagrams
of
isotopy
are
from
of
sai d the
II or
dis
to be
other
type
III.
II .
Ill .
Generators
Thus
the w r i t h e
t h e or y
of
regular
writhe
is not
of R e g u l a r
is an
isotopy.
regularly
Isotopy
invariant An d any
isotopic
Unfortunately
(or
simply
stated
problems)
the a m b i e n t
mirror
i ma g es
is not
simple.
of
moves
mirror In
II,
III
fortunately
to
and
so
also
(!)
in
" f l a t ” kn o t
diagram with nonzero its m i r r o r
if y o u
love
isotopy
Perhaps
I will
the
turn a
image. deep
and
problem
some
for
combination
trefoil
into
its
i m age? fact,
this
is not
so!
The
trefoil
is not
ambient
by
C HAPTER VI
isotopic
to
later
the b o o k by
an
in
its m i r r o r
i nva riant
that
image.
the
polynomial
is an
related
the g e n e r a l i z e d
to
(We
signature
I call
invariant
165
shall
prove
methods.)
Here
R—p o ly n o m i a l ,
of
regular
this we
R^.
isotopy,
polynomial
Gv K
by
again
construct The
and the
R-
it
is
formula
GK _~ a-w( K)R K where
w(K)
is
the writhe.
AXIOMS 1.
To
each
o r i e n t e d knot
R„
K.
or
link
ated a Laurent
polynomial
The
is d e n o t e d
polynomial
€ Z[a,a
R^(a,z) It
2.
F OR
is a n
R ^
in
there two
\z,z
of
K ~ K7
— ■> Rk = Rk , .
= R ^
variables
a,z.
*].
inuariant
regular
is a s s o c i
i s o t o p y .*
= 1,
o
R — >0'”+ = aR ,
3.
Remark:
R
= a ~ 1R.
R
- R
As
with
abbreviations cated
patterns Unfolding
gram
s uch as
= zR
the C o n w a y
refe r ar e
to
polynomial,
larger
diagrams
these
diagrammatic
in w h i c h
the
indi
e m be d de d .
Axiom
2,
we
see
that
for a c u r l y
unknot
dia
166
CHAPTER VI
the R
U
R-polynomial
the w r i t h e
w(U)
in
the
f orm
- a W (U > “
The for
returns
th i rd a x i o m
the C o n w a y
no mi a l.
Not
looks
just
polynomial.
But
at all!
View
R t, = aR ^
K = a
We
see
that
polynomial.
*),
components. of
E xerc is e . split
B
unlink
R, it
of
that
if
= z
an u n l i n k is u s e f u l of
reader
of S e c t i o n
Show
R,
rk
with
the
following
the C o n w a y
poly
calculation:
= a
the v a l u e
[As
is not
identity
"I
R6
Rk
In fact,
6 = z * (a-a
version
=
r l
R
the e x c h a n g e
= a
“ 1D
•n
2
the
like
R
c an
(a-a
can
).
receive
a nonzero
to r e c o r d on a
see,
spl i t R
is a
unlink
of
two
script-
18.]
= 6
n-components
6 0
then
••• R^
0
= 6n n
denotes ^.
a
CHAPTER VI Exerc1 s e .
Show
that
R
,(a,z)
= R^f-a K
K the m i r r o r - i m a g e s u r i n g all
The
diagram
that
167
-1
,z)
is o b t a i n e d
1
where
f rom
K ‘
K
is
by m e a
the c r o s s i n g s .
generalized
p o 1y n o m i a 1
G^(a,z)
is d e f i n e d
by
the
e q u a t i on
Since
R
that
Gj^
is
= a R ^ an d
R—
= a
invariant
under
moves
the g e n e r a l i z e d topy.
polynomial
[We be g p a r d o n
o rder!
G
ca m e
consistent.
Exerc is e .
first,
for a
Show
the e x c h a n g e
logical
that
that
The foil.
G
,(a,z) K *
for
T
Hence
of a m b i e n t and
here
and
iso
logical
that
define
R R
is by
path.]
polynomial
satisfies
c om e
= zG — w
- a
= G„(-a K
calculation
calculation
G
once
identity
time has
The
with
prove
at
III.
historical
do not
start
II a n d
invariant
the g e n e r a l i z e d
aGy^ Show
I,
reversing
a n d we
[K 8 ] , or
Se e
R = aW ^ ^ G
for
is an
^R.— ► j**' f ° l l ° ws
*,z).
to c o m p u t e
R
and
exactly parallels
G the
for
familiar
:
T
the
L
tre
CHAPTER VI
168
Thus T = .* .
T © L ,
L = L
T = T 0
(L © U ) ,
.*.
= RjjT +
Since
R^
clude
that
= a,
0 U,
Z ( R ^ + Z Ry ) •
Rj-= 6(=
z
* (a-a
and
Gt „
. . Note ----- » -a a i 1 ent
to
(2a - a
-2 G^, = (2a -a
*.
G^
k no t
con
A z 2a , - a -1 +
= a _3RT
-4. 2-2 ) + z a is not i n v a r i a n t tha t the
u n d e r the s u b s t i t u t i o n trefoil
i s no t equ iv a -
image.
is a n o t h e r
figure-eight
we
+ z^a
Thi s p r o v e s
its m i r r o r
Here
*)
= a _ W ^T ^RT
that
R^ = a,
= a + z6 + z a = a + a
R^, =
an d
2
R,p = a + z(6 + za)
.' .
*))
K:
sample
ca lculation.
This
time
for
the
169
CHAPTER VI
H er e
an d
K = K €
L - L 0 U.
Hence
K
(L 9 U)
with rk
= “ _S
r
=
l
a 6
R — = aa
-1
1
.
Thu s rk
=
a
Note the
that
w(K)
-2
this
kn o t would What
shall
A
,
+ a(a-a
ha p pe n . not
prove
) - z
2
R„ = K
to
that
is
this
Since
its m i r r o r
R„(a,z) K
so o b v i o u s to
for
K
R v ! =R v . K K
isotopic
iso topi c
diagram the
that
its m i r r o r
the
Let
writhe.
that
K
we
knew
^,z).
f igu r e-e igh t
im a g e .
In
K
be a knot K
diagram
is a m b i e n t
with
fact,
isotopic
ze r o
to
f the d i a g r a m s
figure-
image,
= R„(-a K
of
following
MIRROR THEOREM. Suppose
-L
Al s o
Note be
the
2 Rt
Hence
is a m b i e n t
ma y
z
Rl
knot.
kno t i s r e g u l a r 1v we
z
= 0.
figure-eight
e i g ht
+
rk
and
K‘
are
regularly
iso to p ic .
i K'.
Then
CHAPTER VI
170
In or d e r
to p r o v e
another
invariant
degree
d(K).
of
the u ni t
the kn o t
of
The
this
regular
Whitney
ta n ge n t
diagram.
r e s ul t
vector
we n e e d
isotopy.
degree to
to
This
measures
is the
the u n d e r l y i n g
Combinatorially
it
introduce
yet
the Whi tney total
plane
is d e f i n e d
turn
curve
of
as
foilows: 1 . d( 4 ) = d( X
splicing
disjoint
= d (X ) + d (Y )
all
the
circuits
of
the
sum of
±1
For
e x am p l e ,
of
of
circles
in
curves
is a d i s j o i n t
in
the plane.
)•
the d i ag r am ,
(the se
the d i a g r a m ) .
in
X U Y
) = d( X
crossings
collection
if
ar e
T he
for
ea c h
Seifert
the
case
of
the
we
obtain
called
Whitney
the
degree
cir c ui t . trefoil:
= >
d(T)
= >
d(K)
-
2.
T and
for
K
the
figure
eight:
W
=-1.
is
a
171
CHAPTER VI
Since crossings e rt y
of
Whitney in
the W h i t n e y
the u n d e r l y i n g and G r a u s t e i n
the
same
We will s t a te
doe s
or u n d e r - c r o s s i n g s
the p lane ar e
have
degree
that
generated
by
[Wl]
depend
it a c t u a l l y curve
proved
upon
measures
i m me r si o n. that
r e g u l a r 1v h o m o topic
two
over a prop
In
fact,
immersed
i f an d
only
curves
i f they
Whi tney d e g r e e . not
it
pl ane
not
explain
regular
is c o m b i n a t o r i a l l y the p r o j e c t i o n s
of
h o m o topy h e r e
except
equivalent
the
the m o v e s
to
II a n d
to
relation
III.
T ha t
i s , by
and
It
is a n i c e
exercise
an
invariant
of
underlying Trick of
(this
this
this
to p r o v e relation
that (see
the W h i t n e y - G r a u s t e i n the
reader
chapter!):
has
the W h i t n e y [Kl]).
Theorem
already
Th e is
degree basic
is
move
the W h i t n e y
encountered
in S e c t i o n
3
CHAPTER VI
172
RH
RK
RK
RK
In o rd e r
to g e n e r a l i z e
the
crossings
Thus
we h a v e
and
the
the W h i t n e y
create
a regular
fundamental
tri c k we
shall
include
isotopy:
cur 1- c a n c e 1 1 ing
regular
iso-
topy :
On
the
o th e r
isotopic regular one
(Pr ov e
isotopy
can prove
invariance
the
Theorem
PROPOSITION.
ly
is no t r e g u l a r l y
to
Graustein
ent
hand
isotopic iso topic
Let to
following (See
K
the w r i t h e . )
generalization
by u s i n g
the
As a result, of
the W h i t n e y -
[ W l ] , [ T R ] .):
and
the un k no t .
if a n d
of
this
o nl y
if
K7
be knot
Then
K
they hav e
diagrams and
the
K7 same
each a m b i are
regular
writhe
and
CHAPTER VI
the
same
Whitney
173
K ~ K 7 w (K ) = w (K 7)
degree:
and
d (K ) = d (K 7 ) .
We
omit
obtained
by a r e g u l a r
of a s t r i n g
and
the p r o o f
of
curls
the a p p r o p r i a t e
when
it
it
is
time
M IR R O R THEOREM. w ri the . K
Then is
Proo f: suf fices ing the
that
isotopy
remark
that
to a n o r m a l
the
for m
result
is
consisting
such as
cancellations
Since
to p r o v e
K
Let K
using
the W h i t n e y
t rick
isotopic
regular that
means
(appropriately
to
that
» K*
and
curly).
Prove
this
» K'
to
is an a m b i e n t given
K
that
ze r o
if a n d
o nly
isotopy,
it
» K ~ K*.
Assum-
is r e g u l a r l y C
where T hu s
C
we h a v e
K ~ K ' # C.
(E x e r c i s e :
with
t K ‘.
» K ~ K ‘
i K ~ K'
diagram
isotopic
isotopy
to p r o v e
sum of
the
be a knot
Is a m b i e n t
regularly
connected
diagram
but
is a p p r o p r i a t e .
Now
if
here,
last a s s e r t i o n . )
isotopic
to
is an u n k n o t
CHAPTER VI
174
Since additive
the W h i t n e y
under
d e g r e e an d
connected
the w r i t h e
sums ( e x e r c i s e )
we
are
see
w(C)
= 0
(because
w(K)
= w ( K ')
d(C)
= 0
(because
d(K)
= d ( K !)).
each
that
= 0)
a nd
By
the p r o p o s i t i o n
K ~ K ‘.
T hi s
Th e
ally
knots
a problem
for
G
li st e d G,
and
in our We between
Theorem f ro m in
the
(or at
R).
The
shows
that
that
proved
the p r o b l e m
reader of
isotopy
the is
this
[ K 8 ] for a p r oo f
for
C ~ 0
and
hence
■
(oriented)
regular
the b e g i n n i n g
to
follows
the proof.
their
We h a v e not
Remark:
then
completes
Mirror
guishing
it
mirror
of
i ma g es
distin is a c t u
c a te g o r y .
consistency
of
referred
the p a p e r s
section
to for
the a x i o m s
discussions
the
L-polynomial
of a
regular
discussed
appendix. conclude the
with a picture
figure-eight
an d
its m i r r o r
isotopy
image.
of
175 chapter
VI
CHAPTER VI
176
R e m a r k on W e i I - D e f i n i t i o n :
Producing a s tandard unkno t
R e c a l 1 that
in a s t an d a r d u n k n o t . s p 1 i c in g a c r o ss ing
n e a r e s t to b a s e - p o i n t
r e s u 1 1 s in a split
s pl i ce at
uni i n k .
L,
2
p
K This
fact
L
is
the ke y
well-definedness polynomial, To
see
obtained T hu s are
or
the
the
from
and
to a n y
invariance
by
the d i f f e r e n c e that
n
suppose
switching
K = S S .•••S.K. n n-1 1
Assume
of
argument
either
proving
the
the g e n e r a l i z e d
R-polynomial.
issue, K
inductive
1
Assume
between
is a d j a c e n t
that
K
is an u n k n o t
crossings that
labelled
l , * # # ,n.
the c r o s s i n g s
switched
K
an d a s t a n d a r d u n k n o t
to
the b a s e - p o i n t
as
K.
s ho w n
be 1o w : n
|n
— •
>------------— •------------------ »
P
P K
I |
K
K = S S • • -S.K n n-1 1
177
CHAPTER VI n Then
(As
R„ = K
+ z y e (K)RE.S. • • • S 1K. L nv ' 1 l-l 1 i= l
K
in C h a p t e r
case.
3 of
these notes,
It c a n be h a n d l e d
lem ma a b o u t
there
directly
invariance under
is a n o t h e r
or by
basic
first p r o v i n g
cyclic permutations
of
a
switch
ing e 1e m e n t s .) If we
s li d e
the b a s e p o i n t
n
•
through
the c r o s s i n g we get n
»
•
9
»
1.)
of h a n d l e s
is o b t a i n e d
from
first h o m o l o g y of b o u n d a r y In oth e r in F
components.
f
,
= 1
181
+ 1
the
g roup
components
words,
standard
by a d d i n g
of
the g e n u s form
disks
for to all
182
For
CHAPTER VII
one b o u n d a r y
DEFINITION the
genus
7.1.
c om p o n e n t ,
Let
K,
of
K
2g(F)
= p(F).
be an o r i e n t e d knot
g(K),
Is
the m i n i m a l
or
u a l ue
link.
Then
g(F)
of 3
among
all
sp an
K.
connected,
S i m i l a r l y , the val ue
faces . where
p(F)
of By
our
h(K)
Example: of g e n u s
Is
r an k
among
K
we ha ve
that g(K)
it w o u l d be u n k n o t t e d ) .
is 1 .
K,
of
the n u m b e r
have
surfaces
c o n n e cte d,
formula,
Any knot 1 m us t
oriented
p(K),
F C S
is
oriented 2g(K)
of b o u n d a r y
that
the m i n i m u m spanning
= p(K)
- JJ-(K) +
components
is k n o t t e d an d b o u n d s = 1
T h us
(since the g e n u s
if of
sur
K.
of
a su r f a c e
it b o u n d e d the
1
a disk
trefoil
kno t
183
CHAPTER VII
Let underlying
U
K
be a k n o t universe
is a p l a n a r
(or
(the p l a n a r
graph with
ces.
By E u l e r ' s
edg es
ar e
Formu la ,
incident
link)
di ag ra m and
let
U
be
its
graph).
R r e g i o n s . E e d g e s . a n d V ver t iwe h a v e
to ea c h vertex,
V-E+R
= 2.
we a l s o
have
Since
4
4V = 2E
184
CHAPTER VII
or
2V = E.
regions
S
U)
denote
(refer
PROPOSITION
7.2.
S
circles F
of
Proof:
F
L et
e^
are
U
g i v e n by
up
There
ar e
two m o r e
K.
g(F)
= i
We k n o w
know
V-E+S
2-R+S
= l-p(F).
that
= V-2V+S H
Pq
= 1,
= -V+S
spanning ha ve
Then
type,
surface
p components,
the r a n k a n d
obtained
w here
f rom
the
to e a c h S e i f e r t
the n u m b e r
e^ = V,
= P 0~"P 1 + P2
K
(R-S-jx) .
one 2 -c e ll
denote
for
formulas
= R -S - l
Then
K
Let
re gions. the
circuits
P r o p o s i t i o n 5.8).
the S e i f e r t
to h o m o t o p y
c o mplex.
of S e i f e r t
p (F)
by a d d i n g
e 0 _ e l+ e 2 = 1,2).
be
R
and
(k = 0 , 1 , 2 )
resulting
5,
link d i a g r a m
is,
1-complex
F
Let
or
Seifert
the n u m b e r
to C h a p t e r
for a knot
g enu s
R = V+2.
than v e r t i c e s .
Let (or
Therefore
e^
of
= E,
k-cells e^ = S.
Pfc = r a nk H k ( F )
p \ = P ( F )» = 2-R+S.
P2 =
Therefore
circle. in
the
We h a v e (k = °* we
185
CHAPTER VII
Seifert
surface
In the
circuit
type
II circu it , the b o u n d a r y solution the g i v e n
1 ows :
is
of
pre s en t .
the p l a n e
supposed
in the usua l
into
or
two
for
link,
(A type
even
II
regions,
this
to a d d a d i s k
drawing,
each
II c ircuit.
circuit"
This
to
the
the n e i g h b o r h o o d
d i s k has an u n c l e a r
to d r a w a "t r a c e r
type
for a k n o t
to
circuits.)
that we are but
indicated a method
surface
II c i r c u i t s
divides
containing Seifert We k n o w
I have
the S e i f e r t
there a r e
Seifert
K is o b t a i n e d by a d d i n g a d i s k the c u r v e a.
fi g u r e above,
understanding when
for
tracer
s t ru c tu r e. a
type of
My
corresponding
is d r a w n as
fol-
to
186
CHAPTER VII
Tracer Thus,
it
follows
necessary. new
become these
bounded regions
that
a
between
neighborhood
the by
the
type
T hu s
the
tracer
of
and
II c i r c u i t
we h a v e
proved:
the k no t
the old
to
is o r i e n t e d it
crossing
traces.
it w h e n e v e r d i a g r a m as a
the dia g ra m ,
I circu i ts .
the di s k a d d e d
a
on
over-passes
tracer
type
II circuit,
d r a w out a p i c t u r e
The n e w c o m p o n e n t to
type
If we d r a w
component
regions
the
Circuit
The
of
type
II
disks
the
circuit filling
the b o u n d a r y
the o r i g i n a l
in
then
of a
type
the o p p o s i t e
in
I.
direction
187
CHAPTER VII
PROPOSITION gram.
7.3.
Let
be
the d i a g r a m ing
tracer
Let
these
from
circuits trac er
only
method
of
representing
Here
is a
Does
every knot
and
fundamental
surf a c e ?
links as we
shall
see shortly.
bound
i ^j .
for
surface
calculations
later
the S e i f e r t
some
classes
It
is
will on.
s urfaces:
its m i n i m a 1 g e n u s for
K.
on a of k n o t s
fa ls e in gene r al ,
the g e n e r a l i z e d p o l y n o m i a l .
See
the
[M] by H u g h Mo rton.
While ogy b a s i s F,,,. K
of
is true
in
U U * • *U
is a d i s k w i t h
p r o b l e m ab o u t
Th i s
overpass
circuit
F^,
to
the S e i f e r t
certain
( 1i n k ! a c h i e v e
by an a p p l i c a t i o n paper
for
be
circuits and
D^flD^.=0
And
be p a r t i c u l a r l y u s e f u l
Seifert
I Seifert
(i = 1 , • • • ,k) a^.
ar y
K'
Let
a 1 ,a 0 ,•• • ,a, .T h e n 1 2 k
labelled
is a m b i e n t i s o t o p i c
link d i a
disjoint
II S e i f e r t
type
be
type
where
This
by a d d i n g
or
K.
s u r f a c e for
K
for ea c h
circuits
has
(ii)
be an o r i e n t e d knot
the S e i f e r t
obtained
(i)K'
K
Let
Now
we're
at
it,
let's
for Fw K
l oo k i n g at is a p lanar
o b t a i n e d as a c h e c k e r b o a r d It o nl y
leaves
Consequently,
remark
the p l a n e at
on h o w the
sur f a c e . pattern the
trac e r
That
from
to see a h o m o l
is,
it
is
the d i a g r a m
twists
is S eneratec* by
surface
c yc l e s
K'.
188
CHAPTER VII
{c|c
We
encircles
orient
c
Since tured by
white
F^,
regions.
tracer h a v e by
has
regions,
For
example,
this a c c o u n t = 6.
f o r m u l a of
P r o p o s i t i o n 7.2.
s ince a
Note
bounds
a disk
Ex er c i s e . the g e n e r a l
in
of
all n ot e
k
is
in
fi g u r e
—1
that
this
In fact,
denotes
that
the n u m b e r
an d is
the b o u n d e d
on p.
of
185,
we
p ( F ^ x) = 7.
in a c c o r d w i t h
H^(F^)
has
We h a v e a d d e d homology
of
k
to o b t a i n a b a s i s tracer
circuits
for
the
as b a s i s c^
c y c le s )
F^.
E x p l a i n h ow c ase
(~
r a nk
where the
v
the p l a n e p u n c
c o un t
{c ^ ,c ^ , , c ^ ,c*-,c ^ ,c ^ }.
c^+c^+c^+c^ ~ a
orientation
that
H^(F^),
=p (
p(F„) K.
cycles
see
to o b t a i n
Therefore
the
we
= r an k H ^ ( F ^ / ) - k
ci r cles.
the d ia g r a m } .
type of
In c o un ting,
Then
in
the p l a n a r
the h o m o t o p y
regions)-l.
r an k ^ ( F ^ )
region
compatibly with
the w h i t e
= #(white
a white
^j ( F ^ ) ,•* • ,
in •
and
CHAPTER VII
G iv e or
a procedure
189
for d e c i d i n g w h i c h w h i t e
cycles
to r e t a i n
t h r ow away.
SEIFERT PAIRING We n o w d e f i n e embedding
of a n o r i e n t e d
an d a c y c l e ing
a
normal
0(a,b)
on
0 =
to
: H^( F )
lk(a It
,b). is a n
the e m b e d d i n g Seifert
used
it
to
F,
small
direction
p ai r i n g . of
a
a very
pairing
an a l g e b r a i c m e t h o d
let
a
amount F.
T h is
S -F
this,
.
Given
the
3
---» Z
the
invariant
of
3
,
of p u s h -
the p o s i t i v e
we d e f i n e
by
the
F C S
result
along
the S e i f e r t
formula
is a w e l l - d e f i n e d , the a m b i e n t
bilinear isotopy
cla s s
F C S'*.
invented a version
to be
d enote
into
Using
x H ^(F)
F C S
x
investigate branched
s inc e p r o v e d
of
this p a i r i n g
covering
k n ot
in [ S ] .
spaces.
extraordinarily useful
a nd h i g h e r - d i m e n s i o n a l
Example
surface
for m e a s u r i n g 3
theory.
7 .k:
G
a
b
a
-1
1
b
0
-1
in b o t h
He
It has c lassical
190
CHAPTER VII
The
surface
points
out
F of
is o r i e n t e d the page,
linking
0(a,a)
parallel
c op y
be
computed
=
of
lk(a a
so
towa r d ,a),
along
that the
the p o s i t i v e n o r m a l reader.
a
m a y be
the
surface.
fro m a d i s k w i t h bands,
For
the
self-
r e p r e s e n t e d by a T h us
by c o u n t i n g
0(a,a)
can
c ur l s
w ith
sign.
Example
7.5:
0
a
b
a
-1
b
0
Note:
0
a+b
b
1
a+b
0
1
0
b
0
0
0(a + b ,a + b ) = 0(a ,a ) +0(b ,a ) + 0 ( b ,b ) = 0
T hu s
these p a i r i n g s
embeddings
are
are
isotopic:
6'
c
d
c
0
1
d
0
0
is o mo r ph i c.
In fact,
these
two
CHAPTER VII
191
r?n ~ / ° n ~ ~ fir*■>
We entirely
can, in
if we wan t topological
to do
it,
script.
indicate
a banded
surface
Thu s
represents
the
surface:
192
CHAPTER VII
Exerc is e . face
Determine
the S e i f e r t
pairing
for
this
sur
F.
SEIFERT PAIRING FOR THE SEIFERT SURFACE Now Seifert
let's w o r k out an a l g o r i t h m pairing
f rom a S e i f e r t
into b a n d - f o r m ) . white in
cycles.
F ^ , .)
diagram
Here
ing
Thus
we m u s t
is a p o s i t i v e
sponding
these
the c y c l e s their
0 (a,b)
c r os s in g .
a
Then
is g e n e r a t e d by
b
for
Th e
labelled and in ord er
drawn.
to c o n t i n u e
regions.
the
contribution
local
Let's of
in
the
shaded,
cycles
the w h i t e
the
6 (a,b).
linking number
surface
it
regions
how each crossing
labelled.
are
pushing
encircling white
wi th Sei fert
intersect
around
0 (b,a)
H^ ( F ^ )
the S e i f e r t
and
the
(w i t h o u t
determine
regions
m us t
courses
and
to
computing
surface
circles
c r o ss i ng ,
regions to
that
( Th e se ar e
contributes
and white
that
Recall
for
corre Note follow wr ite this
193
CHAPTER VII
Note
that
number
of
negative
a*b
= +1
cycles
on
0 ( a ,b)
=
0 ( b ,a)
= 0.
also, the
+1
where
x*y
surface.
(The
denotes signs
intersection
rev erse
for a
crossing.) Mr
T he
self-linking
(Note:
The
contribution
c yc l e s
is
0(a,b)
bounding white
c o m p a t i b l y w i t h an o r i e n t a t i o n
=
regions
for
= 0(b,b). are all
the w h i t e
oriented
region
itself.)
0 ( a ,b)
= +1
0 ( b ,a)
= 0
0 ( a ,a)
= 0 ( b ,b)
= -1/ 2
0 ( a ,b ) = 0 ^ 0 ( b ,a)
= -1
0 ( a ,a) = 0 ( b ,b ) = +1/2
194
CHAPTER VII
For
e xample:
Here
a
look at
and two
Exerc is e .
b
interact
crossings
Compute
at
on l y one
to c o m p u t e
the S e i f e r t
c ro s si n g.
0 (a,b)
pairing
0 (b,b).
a nd
for
But we
K
of
Figure
on
the
7.1.
Exercise. face F.
Let
Show
x*y that
denote for all
intersection number
sur
x, y € H^(F),
0 ( x ,y )- 0 (y,x) = x •y .
Hint: general
Do
for S e i f e r t
case.
following be
it
To do
description
two d i s j o i n t
surface bounding t r a n s v e r s a l ly.
surface
the g e n e r a l of
oriented
first. case
Then
it h e l p s
l i nk i n g numbers-' curves.
p.
I so t o p e
Then
lk(a,/3)
a
Let so
= a*B.
B that
Let
try
the
to h a v e a ,p C S
the 3
be an o r i e n t e d a
intersects
B
CHAPTER VII
195
e oc* B = -±.~
> [Why
is
this
E xerc is e . that
this
independent
Prove,
of
the c h o i c e
using Seifert
description
of
(or
linking
of
B?]
spanning)
i mp l ie s
our
s urfaces, original
description. Now
return
to
the
formula
0 ( x ,y ) - 0 ( y ,x)
= x*y,
c o n t e m p late
0 ( x , y ) - 0 (y,x) = l k ( x * , y ) - l k ( y * , x ) = lk(y,x*)-lk(y*,x) =
lk(y,x*)-lk(y,xx )
= l k ( y ,x - x x ) = y- B = x*y.
CHAPTER VII
196
D I F F E R E N T S U R F A C E S FO R A given knot s ur f aces.
For
link can h a v e m a n y d i f f e r e n t
exam p le ,
ra th e r
different
f er e nt
surfaces
two
Seifert
isotopic
surfaces.
s p a n n i n g a k n ot
Th e a n s w e r Consider
or
ISOTOPIC KNOTS
is,
f o l l o w i n g wa y
1)
Cut
out
2)
Take a
will
H o w ar e all
related
in p r i n c i p l e ,
the
diagrams
spanning have
the d i f
to one a n o t h e r ?
surprisingly
to c o m p l i c a t e
simple.
a spanning
sur-
f ace : two discs, tube
jointly
S
fro m
ary attached Th i s
is c a l l e d
doing a
1
.
x I
an d
the
surface,
to
dD^
embed
it
but
with
and
1-surgery
to
s uc h f rom
reverse
the
that F
a and
bounds cap
off
consists a disk w ith
two
the
3
d is -
tube b o u n d
surface.
F
operation
S
^ 2'
F
Th e
in
af ter
surgery
in f i n d i n g a c u r v e 3
S -F. D
2
‘s.
Then
cut
out
a a
on x I
F
197
CHAPTER VII
X i
af ter Thi s
is a
reduces
O-surgerv.
It
sii p l i f i e s
surface
(i.e.,
g enus).
These
two
surgery
with
the
same b o u n d a r y
faces
the
D E F I N I T I O N 7.6.
Let
opera
F
ions g i v e us d i f f e r e n t
and
F'
be
oriented
sur-
surfaces
with
3
boundary are F
that
are
embedded (F g F')
S-eguivalent
by a c o m b i n a tions
of
S
in if
.
We
F'
say
may
O-surgery,
F
that
be
F'
and
obtained
from
1-surgery and ambient
isotopy.
T H E O R E M 7.7
[LI].
Let
F
and
F'
be
connected,
oriented 3
spanning
surfaces
for a m b i e n t
and
are
Then
F
P ro o f
sketch :
F'
i so topic
L,
links
L'
C S
S-equivalent.
3 » S
3
is
a
: S*
M = (FxO) face where
»
U a(S^xI) in
an d
suppose
from
that
L = a(S
get a n e m b e d d i n g
X, U
i x I
isotopy
T h e n we
x I
embedded W
X = S
the a m b i e n t
L / = a(S^xl). via
Let
.
1
xO)
(F*xl), then
is a 3 - m a n i f o l d
On e
then
embedded
this
is a
s hows in
S
that 3
x I
to
of an a n n u l u s
a( A , t ) = ( a (X , t),t).
3 S x I.
a:S
x I.
If we
in
f orm
closed
sur-
M = dW W
ca n be
X
CHAPTER VII
198
arranged points to
of
so
that
2
type
It m a y be
equivalences
is o b t a i n e d
Now surfaces. tube.
2
x +y -z
the O - s u r g e r i e s
Re m a r k :
a
(S xt) fl W
a nd
of
2
has
2
or
2
-z -y +z
1-surgeries
i n t er e st
between Seifert
on l y M o r s e
to
2
.
critical
These
correspond
we d e s c r i b e d
e arlier.
look d i r e c t l y at
surfaces
for d i a g r a m s
the
S-
that are
from
consider Suppose Then
the S e i f e r t that
H ^ (F ' )
F'
= H^(F)
pairings
for
is o b t a i n e d © Z © Z
S-equivalent
f rom
where
F these
by a d d i n g two
199
CHAPTER VII
extra
factors
are
a nd an e l e m e n t so
that
a*b
We
then h a v e
g e n e r a t e d by a m e r i d i a n
b
that p a s s e s
where
0(a,a)
Because
pairing
= 0,0(a,b) for all
for
of
the
row
An e n l a r g e m e n t Mo r e g e n e r a l l y , S-equivalent tion of pos e b as i s of
of
P
change.)
we w r i t e
and
the
tube
a,
oriented
I
0
0
0
1
P
0 0.
can be
0
and
obtained
Z.
enlargements
and
0 g \p.
If
0
^ from
where
over
as above.
Let 0Qd e n o t e
a_
e0
0
0
0
1
b| P
0
n
0 = a
on c h a n g e
of b a s i s
'
is c a l l e d an
(0 — » P 0 P'
i nv ertible and
b ec omes
0
this k i n d
and
is a c o l u m n v ector.
a 0
two m a t r i c e s
if
enlargement)
lent,
of
congruence P,
tube
0(b,a) = 0
T h e n we h a v e
(0,0,1),
’0 O
= 1, x € H^F).
F.
is a row vector,
p
the
= 1.
0 (a ,x ) = 0 ( x ,a ) = 0
the S e i f e r t
once a l o n g
for
Th i s
S-equivalence. are 0 P'
said
by a c o m b i n a is
the
trans
corresponds
contractions
an d
to be
ar e
to
(reverse
S-equiva
200
CHAPTER VII
COROLLARY or
links w i t h
F' \p
7.8.
be
the S e i f e r t
spanning
0
Let
K'
and
connected
K'}.
(for
K
Let
be
pairing
be a m b i e n t F
surfaces
F'.
0
Then
K)
(for
pairing
the S e i f e r t
for
isotopic knots an d
for F
and
\p
a nd are
S -e q u i v a l e n t .
I N V A R I A N T S OF
DEFINITION the knot
S'EQUIVALENCE
7.9.
or
Let K
link
F
be a c o n n e c t e d 0
and
spanning
the S e i f e r t
pairing
surface
for
F.
for
Define (i)
The d e t e r m i n a n t D
(ii)
denotes
(iii)
the
The
= D(t
formula of
= S i g n (0 + 0')
signature
= D(0+0')
of
K,
func t i on o f
signature
cr( K)
D(K)
w he r e
determinant.
The y o t e n t ial by
K,
of
K,
€ Z[t
* 0 - t 0 7).
cr(K) € Z, Sign
where
\t]
by denotes
the
this matrix.
(See d e f i n i t i o n b e l o w . )
Of not g o i n g be
c o u r s e the g a d g e t s to c h a n g e u n d e r
invariants
of
produced
S-equivalence!
exam p le ,
if
0 =
60
0 a
0------- ^— j— a
1 0 .
Hence
they will
and
D(t
0 o'
— ^---- q — j-
.a
V
d e f i n i t i o n are
K.
■0 For
in this
then
0 + 0'
=
0 0.
0 - t 0 7) = D(t
0 Q -t 0 ^)
because
For over
Z
(the
the
s i g na t ur e ,
201
recall
M
c a n be d i a g o n a l i z e d
rationals)
or over
positive
d ia gonal
diagonal
ent r ie s .
the
CHAPTER VII
formula
congruence
The
Sign(M) cl a s s
of
Sign|^
= 0.
is an
invariant
of
invariant
of
invariant
of
K.
and
e+ e_
= e + ~e_. (See
From
its We
Let
denote
Sign(M),
It
is an
[ H N K ] .)
this
shall
also
show
of
is d e f i n e d by
Note
of
the
in p a r t i c u l a r , that
class, that
Q
of n e g a t i v e
invariant
it fo l l o w s
S-equivalence
over
the n u m b e r
the n u m b e r
sig n at u re ,
M.
that
through congruence
IR.
e ntries,
that a s y m m e t r i c m a t r i x
S i g n ( 0 + 0 /)
hence
cr(K)
an
is an
concordance.
T h e po tent ial
f un c t i on p r o v i d e s
a m o d e 1 for
the C o n w a y
p o 1v n o m i a l :
T H E O R E M 7.10. (i)
If
K
links, (ii) (iii)
If
then
K ~ 0,
If links then
K'
and
are a m b i e n t
0^(t)
K,
K
an d
= (t-t
oriented
= 0^/(t). 0 K (t)
then
iso topic
L
= 1. are
r e l a t e d as below,
202
CHAPTER VII
We h a v e a l r e a d y p r o v e d
P r oo f : K.
= 0
if
disjoint connect face
If
K
is a split
spanning
surfaces
these by a
tube
(i) a n d
link. for
To
see
(ii).
Note
this,
two p i e c e s
of
to form a c o n n e c t e d
that
choose the
link,
spanning
a nd
sur
F.
a
is a m e r i d i a n of
this
type,
then
H^F) S Hj (Fj) ffl H1(F2) ffi Z where
a
= 0(x,a)
generates = 0
We us e surfaces
for
the e x t r a
V x € H^(F), this K,
it
d i s c u s s i o n as K
an d
L.
co p y
of
f ol l o w s follows. Lo c al l y,
Z.
Since
that
0(ct,x)
fi^(t) = 0.
Consider they a p p e a r
Seifert as
CHAPTER VII
We
see
that
H^ ( F ^ )
homology generator L
is a split
and =
Fg,
see
L
may
But
*)
substitution
this
case
= 0
twist.
a
that
while
T hu s
then
= ^
a/_
K.
Hence
determinant
the e x t r a g e n e r
F„ a n d 0^ =
with appropriatechoice
Q
on
Frr. K
it
of bases.
calculation
z = t-l/t. the
f o l l ow s
that
f u n c t i o n are
Th u s
reverse.
fi^(t)
It is
to sho w
that
the C o n w a y
related
= v^(t-l/t).
by
the It
is
Then
t = z + 1/t . H en c e t = z+1________. z+1_____ z+ • • • Using
the n o t a t i o n
z+1 , z+1 z+ • • •
we h a v e
[z+y-^ v x^(z) K
for
the c o n t i n u e d
= fiT,( f z + 1 ]->* ). K k J
vKd) =
We
^---- ,
m
our p o t e n t i a l
to sol ve
on
—
our a x i o m a t i c s , an d
should happen
diag r am ,
= 0(a,a) + l.
now a straightforward
polynomial
one m o r e
(iii).
-g— j,
By
have
it
2ir
is not a split
= (t-t
will
unless in
be r e p r e s e n t e d as
0^- =
amusing
F^,
i s o t o p i c by a
that B f a ' . a ' )
Rema r k :
^ ( F^ - )
than
d i ag r am .
proving If
a tor
ar e
an d
203
fraction
In p a r t i c u l a r ,
204
We
CHAPTER VII
shall
return
Let
Example:
to
T
this
subject!
be a
trefoil
with
nT = D
= Lf"o1 - l*.1
0
= (t-t
*)2 +l
Then
= z 2 +l.
-t T hi s
agrees
G i v e n a k no t
Example: the
tan g le
opposite
Since that
in
w i t h our p r e v i o u s
o b t a i n e d by
orientation.
K
K,
= (t
*-t)(-lk(K))
this
cas e
pute
using
with
the
K
Note
K
is a
surface
that
an d h e n c e
exercise
v
that
AND G^(t)
pa i ri n g. of C h a p t e r
the n u m e r a t o r co p y
for
K.
is m u c h
( C om p a r e IV of
*0-t0').
with
we
see
Therefore Apparently,
easier
to c o m
this d i s c u s s i o n
these n o t e s . )
Q. = D(t
K
is an a n n u lu s ,
= lk(K)z.
K
of
of
two c o m p o n e n t s .
matrix
the C o n w a y p o l y n o m i a l
last
d enote
link of
is a S e i f e r t
the S e i f e r t
TRANSLATING
let
running a parallel
has a s p a n n i n g
0 = [-lk(K)]
calculations.
Therefore
CHAPTER VII
205
nK (t- 1 ) = D (t 0- 1- ^ 0') = D ( t 0' -t - 1 0) •'• Since
0
is
ponent
links,
where
p.
2gx2g
and
of
for knots,
we c o n c l u d e
is the
To o b t a i n K
= D ( - ( t _10 - t 0 /)).
number
v*,, K
we n e e d . Look
of c o m p o n e n t s
at
2 - 2
.3 -3 t-t
E x e r c i s e . Let
T
for 2 - c o m
*) = ( - l ) P + ^Q^(t)
to w r i t e
t +t
T
that
a practical method
z = t-t
that
(2g+l}x(2g+l)
of
K.
oft r a n s l a t i o n b e t w e e n tn + ( - l ) n t n = T v J n
in
terms
the pat t er n :
,
= (t-t
- 1)N2+2
1
. ^- .3 0 0 = (t-t ) + 3 1-31
2
= z +2
-1
3, „ = z+3z.
= tn + ( - l ) n t n and z = t-t *. Show n---------------------------------------- -----
0 = zT .-+T n+2 n+1 n
for
t-t
n
> 0.
* =z
t2 + t -2 = z 2 +2 t3 - t -3 =
z3 +3z
4 _ 4 4 0 t^+t ^ = z +4z +2 5 -5 5 K 3 p. t-t = z +5z +5z
t6+ t-6 Show
that
We for
the
knot.
the c o e f f i c i e n t
can us e
this
second Conway Then
K
= z6+6z4+9z2+2. of
exercise
z^
t^n +t
is
to o b t a i n a c u r i o u s
coefficient
has p o t e n t i a l
in
a^(K).
function
For
in the
let form
n^.
formula K
be a
206
CHAPTER VII
n K (t)
= b 0 + b 1 ( t 2 + t " 2 ) + b 2 ( t 4 - t _ 4 ) + - * - + b n ( t 2 n + t - 2 n ).
f ol l o w s
from our
exercise
a 2 (K)
Exerc is e .
Compute
f u n c t i o n an d
it
that
= b 1+ 4 b 2 + 9 b 3 + 1 6 b 4 + * • -+n2 b n .
Seifert
s ign ature
for
p ai ring, the
determinant,
torus k n o t s
and
potential
links
of
( 2 ,n ) .
type
E xe r c i s e . an d
» K'
show
that
P r ov e is
that
tf(K’) = -cr(K)
its m i r r o r T =
image.
and
when
Calculate
T' = & >
K
is a kno t