This paper classifies genus one knots into three $
u^+$-equivalence classes, showing they are all equivalent to the trefoil, its mirror, or the unknot, based on invariants from Heegaard Floer theory.
Contribution
It establishes a complete classification of genus one knots under $
u^+$-equivalence, linking them to well-known knots using knot Floer invariants.
Findings
01
Genus one knots are $
u^+$-equivalent to trefoil, mirror, or unknot.
02
$
u^+$-equivalence preserves many Heegaard Floer invariants.
03
Classification simplifies understanding of genus one knot concordance classes.
Abstract
The ν+-equivalence is an equivalence relation on the knot concordance group. This relation can be seen as a certain stable equivalence on knot Floer complexes CFK∞, and many concordance invariants derived from Heegaard Floer theory are invariant under the equivalence. In this paper, we show that any genus one knot is ν+-equivalent to one of the trefoil, its mirror and the unknot.
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TopicsGeometric and Algebraic Topology · Botulinum Toxin and Related Neurological Disorders
Full text
The ν+-equivalence classes of genus one knots
Kouki Sato
Abstract.
The ν+-equivalence is an equivalence relation on the knot concordance group.
This relation can be seen as a certain stable equivalence on knot Floer complexes CFK∞, and many concordance invariants derived from Heegaard Floer theory are invariant under the equivalence. In this paper, we show that any genus one knot is
ν+-equivalent to one of the trefoil, its mirror and the unknot.
Throughout this paper, all manifolds are assumed to be smooth, compact, connected, orientable and oriented unless otherwise stated.
1.1. Back grounds and the main theorem
Heegaard Floer homology [16] is a powerful set of invariants for 3- and 4-manifolds and knots in 3-manifolds.
In Particular, the Z2-filtered chain complex CFK∞(K)
[15]
associated to any knot K in S3 is
a very effective tool in studying
knots and Dehn surgeries along knots. Indeed,
from CFK∞(K), we can compute
•
the knot Floer homology HFK(K) [15],
and so we can detect the genus and fibredness of K
[6, 11, 14],
•
the Floer homology groups HF, HF∞ and HF±
and correction terms d(−,s) of all Dehn surgeries along K
[18, 19], and
•
many knot concordance invariants including
ν+, τ, Υ, Υ2, and so on.
(See [4, 8]
for details.)
In this paper,
to improve the understanding of CFK∞, we study
ν+-equivalence (denoted ∼ν+)
introduced by
Hom [4]
and
Kim-Park [7].
Here, two knots K1 and K2 are ν+-equivalent
if ν+(K1#(−K2∗))=ν+(K2#(−K1∗))=0,
where −K and K∗ denote the inverse and the mirror of K respectively,
and ν+ is a Z≥0-valued concordance invariant defined by
Hom-Wu
[5].
This relation is an equivalence relation on knots, and
if two knots are concordant then they are ν+-equivalent.
(We call the equivalence classes ν+-classes.)
By the following Hom’s theorem,
ν+-equivalence can be seen as a ‘stable’ filtered chain homotopy equivalence on CFK∞.
Two knots K1 and K2 are ν+-equivalent
if and only if we have the following Z2-filtered chain homotopy equivalence:
[TABLE]
where A1,A2 are acyclic, i.e., H∗(A1)=H∗(A2)=0.
This theorem shows that determining the ν+-class of knots is meaningful
in terms of CFK∞.
Moreover, the ν+-class of a knot K determines
all correction terms of all Dehn surgeries along K and many concordance invariants
including ν+, τ, Υ and Υ2 of K,
and hence classifying the ν+-classes is useful for computing these invariants.
The aim of this paper is to classify the ν+-classes of genus one knots
by using the τ-invariant [13];
in fact, we found that only three ν+-classes are realized by genus one knots. To state our theorem, we set some notations.
For any knot K, let [K]ν+ denote the
ν+-class of K and g(K) the genus of K.
For coprime positive integers p and q, let Tp,q denote the (p,q)-torus knot.
Theorem 1.2**.**
For any knot K with g(K)=1,
we have
[TABLE]
In other words, any genus one knot is ν+-equivalent
to one of the trefoil, its mirror and the unknot.
Since the τ-invariant is relatively understood,
Theorem 1.2 enables us to determine the ν+-class of many
concrete examples.
For instance, Hedden [2] gives a formula
for the τ-invariant of the positive t-twisted Whitehead double of a knot K
(denoted by D+(K,t)).
By Theorem 1.2,
we can generalize his formula to a formula for the ν+-class
of D+(K,t).
Corollary 1.3**.**
For any knot K and t∈Z, we have
[TABLE]
Next, let us consider the quotient set Cν+:={knots in S3}/∼ν+.
Note that since ∼ν+ is weaker than knot concordance and the ν+-invariant has the sub-additivity,
we can identify Cν+ with a quotient group of the knot concordance group C. So
it is natural to ask how different these groups are.
To give an observation of the question,
we set Fn to be the subgroup of C generated by
the knots with genus at most g.
Let πν+:C→Cν+ be the projection,
and then the sequence {Fg}g∈Z≥0 gives filtrations
[TABLE]
and
[TABLE]
It is easy to show that F1 contains Z∞ as a summand.
(For instance, compute the ω-signature for the “twisted doubles” of the unknot. We refer to [9].)
Therefore, combining it with Theorem 1.2,
we have the following proposition, which shows a big gap between C
and Cν+.
Proposition 1.4**.**
F1* contains Z∞ as a summand, while
πν+(F1) is isomorphic to Z.*
In knot concordance theory, there are few kinds of filtrations with
each level finitely generated. Hence we suggest the following question.
Question**.**
For each g∈Z≥0, is πν+(Fg) finitely generated?
1.2. The idea of proof: Estimating ν+-classes
In order to prove Theorem 1.2, we use a partial order on
Cν+ (denoted ≤) introduced in the author’s paper [22].
We first study this partial order geometrically to give the following estimate for the ν+-class of any knot K.
Here g4(K) denotes the 4-genus of K, and we note that this estimate depends on g4(K) rather than g(K).
Theorem 1.5**.**
For any knot K, we have
[TABLE]
Next, we study the Z2-filtered structure of CFK∞
with g(K)=1 algebraically to obtain another estimate,
and combine it with Theorem 1.5 to prove Theorem 1.2.
As another consequence of such estimates, we have the following discriminant
using the Υ-invariant [17].
Theorem 1.6**.**
The equality [K]ν+=−g(K)[T2,3]ν+ holds
if and only if ΥK(1)=g(K).
1.3. Formal knot complexes and new concordance invariants
To study the algebraic aspects of ν+-classes deeply,
we consider an algebraic generalization of CFK∞ called
formal knot complexes.
(The notion is originally considered in [8].)
In particular, we establish the category of such complexes, and obtain
the formal knot monoidK and the formal knot concordance groupCf, which are analogies of the knot monoid K and
the knot concordance group C, respectively.
Concretely, these monoids are related as follows.
Theorem 1.7**.**
We have the following commutative diagram:
[TABLE]
Here, the bottom map coincides with πν+. In particular, the image of the bottom map is Cν+.
Moreover, we also introduce the genus of formal knot complexes, and
define the genus filtration
[TABLE]
where πν+(Fg)⊂Fgf.
For example, Figure 1 depicts an infinite family of genus one
formal knot complexes, and hence [Cn]ν+∈F1f for each
n∈Z>0.
Here we note that C1 is CFK∞(T2,3).
We prove that the [Cn]ν+ are mutually distinct, which implies
that Theorem 1.2 cannot be proved purely algebraically.
Theorem 1.8**.**
The ν+-classes {[Cn]ν+}n=1∞ are mutually distinct in Cf,
while τ(Cn)=1 for any n. In particular, the complement F1f∖πν+(F1) is infinite.
In addition, we will show that if a formal knot complex C is realized as CFK∞ for some knot K,
then the genus of C is at least g(K). Since Cn has genus one and
τ(Cn)=1 but
cannot be realized by any genus one knot, we have the following result,
which is related to the geography problem discussed in [3].
Corollary 1.9**.**
The formal knot complexes {Cn}n=2∞
cannot be realized by any knot in S3.
In order to distinguish the complexes {Cn}, we introduce an infinite family
{Gk}k=0∞ of invariants of ν+-classes, where
Gk(C) consists of finitely many subsets of Z2.
Since the ν+-class of knots is a knot concordance invariant,
{Gn}n=0∞ also gives new knot concordance invariants.
In particular, the primary invariant G0 has the following properties.
Theorem 1.10**.**
For any knot K, the following assertions hold:
(1)
G0(K)* determines all correction terms of all Dehn surgeries along K.*
2. (2)
G0(K)* determines all of ν+, τ and Υ.*
3. (3)
[K]ν+=0* if and only if G0(K) has {(i,j)∈Z2∣i≤0,j≤0} as the unique element.*
The definition of Gn and explicit formulas for computing the above invariants from
G0(K) is given in Section 5.
In the section, we also discuss the relationship between our secondary invariant G1 and
the Υ2-invariant [8].
Organization
In Section 2, we establish the category of formal knot complexes, and construct the monoid Kf and the abelian group Cf. Theorem 1.7 is also proved in this section.
In Section 3, we prove Theorem 1.5. In Section 4, we discuss algebraic estimates for ν+-classes, and prove Theorem 1.2 and Theorem 1.6.
In Section 5, we introduce the invariants {Gn}, and prove
Theorem 1.8, Corollary 1.9 and
Theorem 1.10.
Acknowledgements**.**
The authors would like to thank Jennifer Hom, Min Hoon Kim and JungHwan Park
for many interesting conversations about the present work.
The author was supported by JSPS KAKENHI Grant Number 18J00808.
2. Category of formal knot complexes
In this section, we establish the category of formal knot complexes.
2.1. Poset filtered chain complexes
Let P be a poset, i.e. a set P with partial order ≤.
For example, we often consider the partial order ≤ on Z2 given by
(i,j)≤(k,l) if i≤k, j≤l.
For a given poset P, a closed regionR⊂P is a subset
such that for any x∈P, if there exists an element y∈R satisfying x≤y, then x∈R. We denote the set of closed regions of P by CR(P).
Let F:=Z/2Z and R be a F-algebra.
In this paper, we say that
(C,∂) is a chain complex C over R
if (C,∂) satisfies the following:
•
C is a R-module and ∂:C→C is a
R-linear map with ∂∘∂=0.
•
As F-vector space, C is decomposed into ⨁n∈ZCn and satisfies ∂(Cn)⊂Cn−1.
(Remark that the R-action does not preserve the grading in general.
We often abbreviate (C,∂) to C.)
Then, we say that C is P-filtered if
a subcomplex CR of C over F is associated to each closed region R⊂P
so that if R⊂R′ then CR⊂CR′.
(Here we remark that CR is not a R-submodule of C in general.)
We call the set {CR}R∈CR(P) a P-filtration on C.
For instance, a Z-filtration {C{i≤m}}{i≤m}∈CR(Z) is
identified with an increasing sequence
[TABLE]
of subcomplexes by the correspondence Fm=C{i≤m}.
Moreover, For two Z-filtrations {Fi1}i∈Z and
{Fj2}j∈Z on C, the set
[TABLE]
defines a Z2-filtration on C.
We call it the Z2-filtration induced by the ordered pair({Fi1}i∈Z,{Fj2}j∈Z).
For a complex C with induced Z2-filtration by
({Fi1},{Fj2}),
Cr denotes C with induced Z2-filtration by ({Fi2},{Fj1}).
For any two P-filtered chain complexes C and C′, a map
f:C→C′ is P-filtered
if f(CR)⊂CR′ for any closed region R.
Two P-filtered chain complexes C and C′ are
P-filtered homotopy equivalent
(and denoted C≃C′)
if there exists a chain homotopy equivalence map f:C→C′ over R
such that the map, its inverse and all chain homotopies are P-filtered
and graded. (Then f is called
a P-filtered homotopy equivalence map.
Particularly, we call the above f a
P-filtered chain isomorphism if f is a chain isomorphism.)
The following lemma immediately follows from the definition of
P-filtered homotopy equivalence.
Proposition 2.1**.**
Let C and C′ be P-filtered chain complexes.
If C≃C′, then for any closed regions R⊂R′,
we have an isomorphism between the long exact sequences of R-modules:
[TABLE]
Here, i:CR→CR′ (resp. p:CR′→CR′/CR)
denote the inclusion (resp. the projection).
Moreover, the above isomorphism induces an isomorphism
between the long exact sequences of graded F-vector spaces:
[TABLE]
2.2. Formal knot complexes
Now we state the precise definition of formal knot complex, and discuss several basic properties of it.
2.2.1. Definition
Let Λ:=F[U,U−1].
We call a tuple
[TABLE]
a formal knot complex if it satisfies the following seven conditions;
(1)
(C,∂) is a chain complex over Λ
with decomposition C=⨁n∈ZCn.
The grading of a homogeneous element x is denoted gr(x)
and called the Maslov grading of x.
2. (2)
{FjAlex}j∈Z is a Z-filtration on C.
This filtration is called Alexander filtration, and
the filtration level of an element x∈C is denoted
Alex(x) (i.e. Alex(x):=min{j∣x∈FjAlex}).
3. (3)
Similarly, {FiAlg}i∈Z is a Z-filtration on C,
called the algebraic filtration,
and filtration levels of elements are denoted Alg(x).
When we regard C as a Z2-filtered complex, we use
the Z2-filtration induced by the ordered pair
({FiAlg}i∈Z,{FjAlex}j∈Z).
4. (4)
The action of U lowers Maslov grading by 2
and Alexander and algabraic filtration levels by 1.
5. (5)
As a Λ-module, C is freely and finitely generated by
elements {xk}1≤k≤r such that
•
each xk is homogeneous
with respect to the Maslov grading,
•
{UAlex(xk)xk}1≤k≤r is a free basis for F0Alex as a
F[U]-module, and
•
{UAlg(xk)xk}1≤k≤r is a free basis for F0Alg as a
F[U]-module.
We call such {xk}1≤k≤r a filtered basis.
6. (6)
There exists a Z2-filtered homotopy equivalence map ι:C→Cr.
7. (7)
Regard Λ as a chain complex with trivial boundary map, and define
the Maslov grading by
[TABLE]
and the Alexander and algebraic filtrations by
[TABLE]
Then there exists a Z-filtered homotopy equivalence map
fAlex (resp. fAlg) :C→Λ over Λ
with respect to the Alexander (resp. algebraic) filtration.
We often abbreviate the tuple
[TABLE]
to C or (C,∂).
Remark**.**
Note that
{UAlex(xk)−jxk}1≤k≤r
(resp. {UAlg(xk)−ixk}1≤k≤r)
is a free basis for FjAlex (resp. FiAlg) as a
F[U]-module. In particular, the equalities
[TABLE]
hold for any i,j,k∈Z.
(These facts also imply that for any element x∈C, both
Alex(x) and Alg(x) are finite.)
Similarly,
{U2gr(xk)−nxk}k∈[n]
is a basis for Cn as a F-vector space,
where [n] is a subset of {1,…r} consisting of elements with
gr(xk)≡n (mod 2), and the equality Uk(Cn)=Cn−2k holds.
As the simplest example,
the tuple
[TABLE]
is a formal knot complex.
In addition, it is easy to see that the following lemmas hold.
Lemma 2.2**.**
For any formal knot complex C,
the complex Cr is also a formal knot complex.
Lemma 2.3**.**
Let (Cˉ,∂ˉ) be a chain complex over F generated by
a finite basis {xk}1≤k≤r with functions
[TABLE]
satisfying the following:
•
The sequences
[TABLE]
define Z-filtrations on Cˉ, respectively.
•
For the induced Z2-filtration ({FˉiAlg},{FˉjAlex}) on Cˉ,
we have a Z2-filtered homotopy equivalence Cˉ≃Cˉr.
•
Regard F as a chain complex over F with trivial boundary map and grading F=F0, and define a Z-filtration by Fˉi(F)=F if and only if i≥0. Then
we have Z-filtered homotopy equivalences Cˉ≃F with respect to
both {FˉjAlex} and {FˉiAlg}.
If we set
•
C:=Cˉ⊗FΛ* and ∂:=∂ˉ⊗1,*
•
Cn:=⨁m∈Z(Cˉn+2m⊗FUm), and
•
FjAlex:=∑m∈Z(Fˉj+mAlex⊗FUmF[U])* and
FiAlg:=∑m∈Z(Fˉi+mAlg⊗FUmF[U]),*
then the tuple
[TABLE]
is a formal knot complex.
In [15], Ozsváth and Szabó associate the Z2-filtered homotopy type of a formal knot complex
CFK∞(K) to any knot K, and prove that it is an isotopy invariant.
To simplify notation, we write CK for CFK∞(K).
Here, we compare formal knot complex with Hedden-Watson’s
abstract infitnity complex.
First, a graded, bifiltered complex
is a chain complex over F
which admits a basis B with functions:
[TABLE]
such that for any a,b∈B, if the coefficient of a in ∂b is non-zero,
then
[TABLE]
In other words, Cn:=spanF{a∈B∣m(a)=n} (n∈Z) defines a grading
and CR:=spanF{a∈B∣F(a)∈R} (R∈CR(Z2)) defines
a Z2-filtration.
An abstract infinity complex is a graded, bifiltered complex
(C,∂,F) satisfying
(1)
(C,∂) is freely generated as a chain complex over Λ
by a finite set of graded, bifiltered homogeneous generators.
2. (2)
Acting by U shifts the grading by −2 and the bifiltration by (−1,−1).
3. (3)
H∗(C,∂)≅Λ, where 1∈Λ has grading [math].
4. (4)
The complex (C,∂,Fr), where Fr is the bifiltration
function Fr(i,j):=F(i,j), is Z2-filtered homotopy equivalent to
(C,∂,F).
Proposition 2.6**.**
Any formal knot complex is an abstract infinity complex.
Proof.
For a given formal knot complex C, we take a filtered basis {xk}1≤k≤r
and set
•
B:={Ulxk∣l∈Z1≤k≤r},
•
m:B→Z:Ulxk↦gr(Ulxk), and
•
F:B→Z×Z:Ulxk↦(Alg(Ulxk),Alex(Ulxk)).
Then (C,∂,F) satisfies the all conditions for being
an abstract infinity complex.
∎
On the other hand, in general, an abstract infinity complex does not satisfy the condition (7) in the definition of formal knot complex.
For instance, Λ with grading shifted by 2n is an abstract infinity complex, but
it is not Z-filtered homotopy equivalent to the original Λ with respect to either Alexander or algebraic filtration.
2.2.3. Basic properties
Here, we discuss several basic properties of formal knot complexes.
We first consider a change of filtered basis.
Lemma 2.7**.**
Let C be a formal knot complex and {xk}1≤k≤r
a filtered basis for C.
(1)
For any l∈Z and a∈{1,…,r},
the set {xk}k=a1≤k≤r∪{Ulxa}
is also a filtered basis for C.
2. (2)
For a,b∈{1,…,r} with a=b,
if gr(xa)=gr(xb), Alex(xa)≥Alex(xb) and Alg(xa)≥Alg(xb),
then the set {xk}k=a1≤k≤r∪{xa+xb}
is also a filtered basis for C.
Moreover, Alex(xa+xb)=Alex(xa) and Alg(xa+xb)=Alg(xa).
Proof.
It is obvious that both {xk}k=a1≤k≤r∪{Ulxa}
and {xk}k=a1≤k≤r∪{xa+xb}
are free bases for C as a Λ-module.
Therefore, the first assertion follows from Ulxa∈Cgr(xa)−2l, Alex(Ulxa)=Alex(xa)−l
and Alg(Ulxa)=Alg(xa)−l.
We consider the second assertion.
Since xa+xb∈Cgr(xa)=Cgr(xb), the element xa+xb is homogeneous.
Next, let ja:=Alex(xa), and then xa+xb lies in FjaAlex.
Here we claim that xa+xb∈/Fja−1Alex.
Assume that xa+xb∈Fja−1Alex. Then
Uja−1(xa+xb)=Uja−1xa+Uja−1xb∈F0Alex,
and we have a linear combination
[TABLE]
where pk(U)∈F[U].
However, the minimal degree of pa(U)UAlex(xa)=pa(U)Uja
is at least ja,
and hence we have Uja−1=pa(U)Uja.
This contradicts the fact that {xk}1≤k≤r
is a free basis for C as a Λ-module.
Therefore, we have xa+xb∈/Fja−1Alex and
Alex(xa+xb)=ja.
Now, it is easy to check that
{UAlex(xk)xk}k=a1≤k≤r∪{UAlex(xa+xb)(xa+xb)}
is a free basis for F0Alex as a F[U]-module.
Similarly, we can check that
{UAlg(xk)xk}k=a1≤k≤r∪{UAlg(xa+xb)(xa+xb)}
is a free basis for F0Alg as a F[U]-module.
∎
Next we consider the rank of formal knot complexes.
Lemma 2.8**.**
For any formal knot complex C,
the rank of C as a Λ-module is odd.
Proof.
Since there exists a chain homotopy equivalence map from C
to Λ such that the map, its inverse and all chain homotopies are
graded and filtered with respect to the Maslov grading and the algebraic filtration,
we have H∗(F0Alg/F−1Alg)=H0(F0Alg/F−1Alg)≅F. In particular, the Euler characteristic of
F0Alg/F−1Alg is 1.
Here, as a F-vector space,
{UAlg(xk)xk}1≤k≤r is a basis for F0Alg/F−1Alg,
and hence r is odd. This completes the proof.
∎
Finally, by using a fixed filtered basis {xk}1≤k≤r, we consider a decomposition
C=⨁(i,j)∈Z2C(i,j) as a F-vector space, where C(i,j)
is defined by
[TABLE]
We call it the decomposition of C induced by {xk}1≤k≤r.
Lemma 2.9**.**
For any R∈CR(Z2), the equality
[TABLE]
holds.
Proof.
By the definitions of CR and filtered basis, we see that
[TABLE]
and
[TABLE]
Therefore, if (i,j)∈R and Ulxk∈C(i,j), then
[TABLE]
and hence Ulxk∈FiAlg∩FjAlex⊂CR.
This implies CR⊃⨁(i,j)∈RC(i,j).
Conversely, if (i,j)∈R and l≥max{Alg(xk)−i,Alex(xk)−j}, then
[TABLE]
and
[TABLE]
This implies Ulxk∈⨁(i,j)∈RC(i,j), and hence
CR⊂⨁(i,j)∈RC(i,j).
∎
As a corollary, we have the following useful lemma.
In this subsection, we check that the tensor product of formal knot complexes is also
a formal knot complex.
Let Kf be the set of the Z2- filtered homotopy equivalence classes of formal knot complexes.
Proposition 2.11**.**
For any two formal knot complexes C and C′, the tuple
[TABLE]
is a formal knot complex, where
p:ΛC×C′↠C⊗ΛC′ is the projection.
Moreover, the set Kf
with product
[TABLE]
is a commutative monoid.
Remark**.**
Note that p(Fj1Alex×Fj2Alex)=p(Fj1′Alex×Fj2′Alex) if j1+j2=j1′+j2′,
and hence the definition of the Alexander (resp. algebraic) filtration is symmetric.
Proof.
The fact that (C⊗ΛC′,∂⊗1+1⊗∂) is
a chain complex follows from
ordinary arguments in homological algebra.
Let {xk}1≤k≤r (resp. {xl′}1≤l≤s) be a filtered basis
for C (resp. C′).
Then
{xk⊗xl′∣1≤l≤s1≤k≤r} is a free basis for
C⊗ΛC′, and
[TABLE]
is a basis for C⊗ΛC′ as a F-vector space.
In particular, the subspace
[TABLE]
is generated by
{U2gr(xk)+gr(xl′)−n(xk⊗xl′)}(k,l)∈[n],
where [n] is a subset of {1,…,r}×{1,…,s}
such that (k,l)∈[n] if and only if gr(xk)+gr(xl′)≡n (mod 2). This implies that
C⊗ΛC′=⨁n∈Z(C⊗ΛC′)n as a F-vector space,
∂((C⊗ΛC′)n)⊂(C⊗ΛC′)n−1
and U((C⊗ΛC′)n)⊂(C⊗ΛC′)n−2.
Therefore, the first condition and a part of the fourth and fifth conditions hold.
Next,
it is obvious that
{spanFp(F0Alex×FjAlex)}j∈Z
gives an increasing sequence of subcomplexes, and
we see that
{UAlex(xk)+Alex(xl′)−j(xk⊗xl′)∣1≤l≤s1≤k≤r}
is a free basis for
spanFp(F0Alex×FjAlex) as a F[U]-module.
Hence the second condition and a part of the fourth and fifth conditions hold.
Similarly, we can verify that the third condition and
the remaining part of the fourth and fifth conditions hold.
Next we consider the seventh condition.
Here we note that it is easy to check that for the trivial case
(i.e. the case of C=C′=Λ),
the seventh condition holds. Indeed, the canonical identification
Λ⊗ΛΛ≅Λ
and its inverse are graded and Z-filtered chain isomorphisms (with respect to both filtrations).
Let fAlex (resp. fAlex′) be a Z-filtered homotopy equivalence map from C (resp. C′)
to Λ with respect to the Alexander filtration.
Then
the composition of fAlex⊗fAlex′:C⊗ΛC′→Λ⊗ΛΛ with the canonical identification
Λ⊗ΛΛ≅Λ
is a Z-filtered homotopy equivalence map
with respect to
the grading {(C⊗ΛC′)n}n∈Z and
the filtration {spanFp(F0Alex×FjAlex)}j∈Z.
Therefore, the seventh condition holds with respect to the Alexander filtration.
In the same way, we can also prove the seventh condition with respect to the algebraic filtration,
and verify that
C⊗ΛΛ≃C,
C⊗ΛC′≃C′⊗ΛC, and if C≃C′′ then
C⊗ΛC′≃C′′⊗ΛC′.
Now, to prove the proposition, it suffices to prove the sixth condition, and this follows from taking ι⊗ι′, where ι:C→C
(resp. ι′:C′→C′) is a map satisfying the sixth condition for C (resp. C′).
This completes the proof.
∎
Now, let K be the monoid of the isotopy classes of knots.
Then we see that the connected sum formula of CFK∞ gives a
monoid homomorphism
K→Kf.
The map K→Kf:[K]↦[CK] is a monoid homomorphism.
Equivalently, the equality [CK#J]=[CK⊗ΛCJ] holds.
2.4. The dual of a formal knot complex
In this subsection, we check that the dual of a formal knot complex
is also a formal knot complex.
Let C be a formal knot complex. Since C is freely generated by
a filtered basis {xk}1≤k≤r as a Λ-module,
the dual C∗:=HomΛ(C,Λ)
is freely generated by the dual basis {xk∗}1≤k≤r.
We use the dual basis to define the Maslov grading and two filtrations on C∗.
Here we note that C∗ is a F-vector space and
{Ulxk∗∣l∈Z,1≤k≤r} is a basis for C∗ as a F-vector space.
Hence we can define a F-linear isomorphism Φ:C→C∗
by Φ(Ulxk)=U−lxk∗ . (Remark that since C is infinite-dimensional
F-vector space, C∗ is not isomorphic to HomF(C,F).) We call Φthe dual isomorphism induced by{xk}1≤k≤r.
Next,
let C/FjAlex (resp. C/FiAlg) denote the subspace of C (as a F-vector space)
generated by {Ulxk}1≤k≤rl≤Alex(xk)−j−1
(resp. {Ulxk}1≤k≤rl≤Alg(xk)−i−1).
Then we have
[TABLE]
In particular, we see that Φ(C/FjAlex)
(resp. Φ(C/FiAlg)) is a free F[U]-module
generated by {U−Alex(xk)+j+1xk∗}1≤k≤r
(resp. {U−Alg(xk)+i+1xk∗}1≤k≤r).
Now, the formal knot complex structure of C∗ is described as follows.
Proposition 2.13**.**
Let ∂∗:C∗→C∗ denote the dual of the differential ∂ on C.
Then, the tuple
[TABLE]
is a formal knot complex. Moreover,
for any formal knot complexes C1,C2,
if C1≃C2 then C1∗≃C2∗.
We call the formal knot complex C∗the dual of C.
Before proving Proposition 2.13,
we prove the following lemmas.
Here, ε:Λ→F is a F-linear map
defined by ε(p(U))=p(0) for each p(U)∈Λ
(i.e. ε maps a Laurent polynomial to its constant term).
Lemma 2.14**.**
We have the equalities
[TABLE]
In particular,
the subspaces Φ(C−n), Φ(C/F−j−1Alex) and Φ(C/F−i−1Alg)
are independent of Φ. (We often denote them by Cn∗, FjAlex(C∗)
and FiAlex(C∗) respectively.)
Proof.
We first note that
Φ(Cn) is generated by {U−2gr(xk)−nxk∗}k∈[n].
Now, Suppose that φ is in Φ(Cn), and then
we have a F-linear combination
[TABLE]
Thus, for any element x=∑1≤k≤rpk(U)xk∈⨁m=nCm,
we have
[TABLE]
Here, since x is in ⨁m=nCm, the coefficient of
U2gr(xk)−n in pk(U) is zero.
This implies that
[TABLE]
Conversely, suppose that
φ=∑1≤k≤rqk(U)xk∗∈C∗
satisfies ε∘φ(⨁m=−nCm)={0}.
Here we note that
the coefficient of Ul in qk(U) is zero
if and only if
ε∘φ(U−lxk)=0.
In addition, for any k∈[n], U−lxk is in ⨁k=−nCk
if and only if l=−2gr(xk)+n,
and hence we have qk(U)=akU−2gr(xk)−n for some ak∈F.
Otherwise, Ulxk∈⨁k=−nCk for any l,
and hence qk(U)=0.
As a consequence, we have φ=∑k∈[n]akU−2gr(xk)−nxk∗.
In a similar way, we can also prove the assertions for Φ(C/F−j−1Alex)
and Φ(C/F−i−1Alg).
∎
Lemma 2.15**.**
Let C,C′ be formal knot complexes
and f:C→C′ be a Λ-linear map.
Define a map f∗:C′∗→C∗ by φ↦φ∘f.
(1)
Fix k∈Z. If f(Cn)⊂Cn+k′ for any n, then f∗(Φ(Cn+k′))⊂Φ(Cn).
2. (2)
If f(FjAlex(C))⊂FjAlex(C′), then
f∗(Φ(C′/FjAlex))⊂Φ(C/FjAlex).
3. (3)
If f(FiAlg(C))⊂FiAlg(C′), then
f∗(Φ(C′/FiAlg))⊂Φ(C/FiAlg).
Proof.
Lemma 2.14 implies that for any φ∈Φ(Cn+k′), the equalities
[TABLE]
hold, and hence f∗φ∈Φ(Cn).
Similarly, we can prove the second and third assertions in Lemma 2.15.
∎
The first, second, third and forth conditions immediately follow from
the arguments above Proposition 2.13, the above two lemmas and the equality UΦ=ΦU−1.
So we first consider the fifth condition. We prove that
{xk∗}1≤k≤r is a filtered basis.
First, xk∗ is in Φ(C−gr(xk)) and hence it is homogeneous.
Next, it is easy to see that
{U−Alex(xk)xk∗}1≤k≤r
is a free basis for Φ(C/F−1Alex) as a F[U]-module,
and xk∗∈Φ(C/F−j−1Alex) if and only if j=−Alex(xk).
These imply that {xk∗}1≤k≤r
satisfies the fifth condition with respect to the Alexander filtration.
Similarly, we can also prove that {xk∗}1≤k≤r satisfies
the condition with respect to the algebraic filtration. Thus, the fifth condition holds.
Next, we consider the seventh condition.
Let fAlex:C→Λ be a Z-filtered homotopy equivalence map
with respect to the Alexander filtration, and gAlex the inverse of fAlex.
Then the dual gAlex∗:C∗→Λ∗ is a chain homotopy equivalence map over
Λ, and
Lemma 2.15 implies that the duals of fAlex, gAlex and all chain homotopies
are graded with respect to the pair
[TABLE]
and Z-filtered with respect to the pair
[TABLE]
Moreover, if we define a Λ-linear map Ψ:Λ→Λ∗
by Ψ(1)=1∗, then
Ψ is a chain isomorphism satisfying
[TABLE]
and
[TABLE]
These imply that
Ψ and the inverse Ψ−1 are graded with respect to the pair
[TABLE]
and Z-filtered with respect to the pair
[TABLE]
As a consequence, the composition
Ψ−1∘g∗:C∗→Λ
satisfies the seventh condition with respect to the Alexander filtration.
In the same way, we can prove the seventh condition with respect to
the algebraic filtration. In addition, the sixth condition also follows from
similar arguments.
Finally, we consider the last assertion in Proposition 2.13.
Suppose that
C1,C2 are formal knot complexes and f:C1→C2 is
a Z2-filtered homotopy equivalence map.
Then Lemma 2.15
implies that
the dual f∗:C1∗→C2∗ is a
Z2-filtered homotopy equivalence map.
This completes the proof.
∎
For knot complexes, the dual complex corresponds to the mirror.
(Note that the knot Floer homology HFK is treated in
[15, Proposition 3.7], while the same proof can be applied to
CFK∞.)
In particular, by combining the above theorem with Theorem 2.5,
we have
[TABLE]
This fact is important in terms of knot concordance.
About dual complexes, we give three more lemmas.
Lemma 2.17**.**
Let C be a formal knot complex.
Then the F-linear map εn:C−n∗→HomF(Cn,F)
defined by φ↦ε∘φ
is a cochain isomorphism (where we see {C−n∗}n∈Z as a graded cochain complex over F).
In particular, we have F-linear isomorphisms
[TABLE]
where the first isomorphism is the isomorphism induced from εn.
Proof.
The equalities ∂∗(εnφ)=ε∘φ∘∂=εn+1(∂∗φ)
show that {εn}n∈Z is a cochain map.
We prove that εn is a F-linear isomorphism.
Let {xk}1≤k≤r be
a filtered basis for C and
Φ the dual isomorphism induced by {xk}1≤k≤r.
Then we see that {ε∘(U−2gr(xk)−nxk∗)}k∈[n]
coinsides with the dual basis for {U2gr(xk)−nxk}k∈[n]. Here we note that
{U−2gr(xk)−nxk∗}k∈[n]
is a basis for C−n∗, and hence εn is an isomorphism.
∎
Lemma 2.18**.**
For any formal knot complex C,
the Λ-linear map Ξ:C→C∗∗
defined by Ξ(x)(φ)=φ(x)
(x∈C, φ∈C∗)
is a Z2-filtered chain isomorphism.
In particular, C∗∗≃C.
Proof.
It is easy to check that Ξ is a chain isomorphism over Λ.
Moreover, for a fixed filtered basis {xk}1≤k≤r for C,
let Φ:C→C∗ (resp. Φ∗:C∗→C∗∗) be
the dual isomorphism induced by {xk}1≤k≤r
(resp. {xk∗}1≤k≤r),
and then Φ∗∘Φ=Ξ.
Hence we have
[TABLE]
These complete the proof.
∎
Lemma 2.19**.**
For any two formal knot complexes C and C′,
the Λ-linear map
Γ:C∗⊗C′∗→(C⊗C′)∗
defined by Γ(φ⊗ψ)(x⊗y)=φ(x)ψ(y)(φ∈C∗,ψ∈C′∗,x∈C,y∈C′)
is a Z2-filtered chain isomorphism.
In particular, (C⊗C′)∗≃C∗⊗C′∗.
Let (A,∂) be a chain complex over Λ.
We call a tuple
[TABLE]
a stabilizer if it satisfies the first to sixth conditions in the
definition of formal knot complex and the following:
Condition**.**
There exists a chain homotopy ΦAlex (resp. ΦAlg) on C connecting the identity and the zero-map
which is Z-filtered with respect to the Alexander filtration (resp. the algebraic filtration).
Remark**.**
The above condition does not imply A≃0.
The relation A≃0 is corresponding to the existence of chain homotopies ΦAlex and ΦAlg
satisfying the above condition and ΦAlex=ΦAlg.
Let C (resp. C′) be a chain complex over Λ satisfying the first to sixth conditions
for being a formal knot complex and
{xk}1≤k≤r (resp. {xl′}1≤l≤s)
a filtered basis for C (resp. C′). Then the tuple
[TABLE]
also satisfies the first to sixth conditions for being a formal knot complex,
where {(xk,0)}1≤k≤r∪{(0,xl′)}1≤l≤s
is a filtered basis for the tuple.
We abbreviate the tuple to C⊕C′.
Lemma 2.20**.**
Let A be a chain complex over Λ
satisfying the first to sixth conditions for
being a formal knot complex.
Then A is a stabilizer if and only if H∗(F0Alex)=H∗(F0Alg)=0.
Proof.
The only-if-part obviously holds. We prove the if-part.
Suppose that H∗(F0Alex)=H∗(F0Alg)=0.
Then, since U:F0Alex→F−1Alex is a chain isomorphism, we have
H∗(F−1Alex)=0 and H∗(F0Alex/F−1Alex)=0.
Let {xk}1≤k≤r be a filtered basis for A.
By Lemma 2.7,
we may assume that Alex(xk)=0 for any k.
Then we see F0Alex/F−1Alex=spanF{pxk}1≤k≤r,
where p:F0Alex→F0Alex/F−1Alex is the projection.
Moreover, it follows from H∗(F0Alex/F−1Alex)=0 that r is even and there exists a subset
{k1,k2,…,kr/2} of {1,…,r}
such that
[TABLE]
This implies that Alex(∂xki)=0 for any 1≤i≤r/2
and
[TABLE]
Now, define a Λ-linear map ΦAlex:A→A by
xki↦0 and ∂xki↦xki.
Then, it is not hard to check that ΦAlex(Cn)⊂Cn+1,
ΦAlex(FiAlex)⊂FiAlex, and
ΦAlex∘∂+∂∘ΦAlex is equal to the identity on A.
This proves the condition for being a stabilizer with respect to the Alexander filtration.
In the same way, we can prove
the condition for being a stabilizer with respect to the algebraic filtration.
∎
In addition, we can easily check that the following lemmas hold.
Lemma 2.21**.**
For two stabilizers A and A′,
the direct sum A⊕A′ is also a stabilizer.
Moreover, for a formal knot complex C,
the direct sum C⊕A is also a formal knot complex.
Lemma 2.22**.**
For two stabilizers A and A′,
and a formal knot complex C,
the tensor products
A⊗ΛA′ and C⊗ΛA are also stabilizers.
Lemma 2.23**.**
For a stabilizer A, the dual A∗ is also a stabilizer.
2.6. ν+-invariant
For any formal knot complex C, we have
[TABLE]
In particular, H0(C)≅F.
A cycle x∈C is called a homological generator
if x is homogeneous with gr(x)=0 and the homology class [x]∈H0(C)
is non-zero. We define the ν+-invariant of C by
[TABLE]
Remark**.**
The above definition of ν+ is originally that of ν−.
However, these invariants are the same, and hence we may define ν+ as above.
Note that the equality
[TABLE]
holds, and hence the value ν+(C) is invariant under Z2 -filtered homotopy equivalence.
Proposition 2.24**.**
ν+(C⊗ΛC′)≤ν+(C)+ν+(C′).
Proof.
Note that
C{i≤0,j≤m}=F0Alg∩FmAlex,
and hence there exists a homological generator
x∈C (resp. x′∈C′) lying in F0Alg∩Fν+(C)Alex
(resp. F0Alg∩Fν+(C′)Alex).
This implies that x⊗x′∈C⊗ΛC′ is
lying in
[TABLE]
Moreover, it is easily seen that x⊗x′ is a homogeneous cycle with
gr(x⊗x′)=0 (and so [x⊗x′]∈H0(C⊗ΛC′)), and
the Künneth formula
H∗(C)⊗ΛH∗(C′)↪H∗(C⊗ΛC′)
implies that [x⊗x′] is non-zero.
Therefore, x⊗x′ is a homological generator, and this completes the proof.
∎
It is easy to see that the value of ν+ is unchanged under stabilization.
Lemma 2.25**.**
For any formal knot complex C and stabilizer A,
we have ν+(C⊕A)=ν+(C).
Moreover, ν+ also has the following property.
Lemma 2.26**.**
For any formal knot complex C, we have
[TABLE]
Proof.
Let {xk}1≤k≤r be a
filtered basis for C.
Then, the element x=∑1≤k≤rxk⊗xk∗ is lying in
(C⊗ΛC∗){i≤0,j≤0}
and homogeneous with gr(x)=0.
We prove that this x is a homological generator.
Let (alk)1≤l,k≤r be the matrix
of ∂:C→C with respect to {xk}1≤k≤r,
i.e. ∂xk=∑1≤l≤ralkxl.
Then its transpose (akl)1≤l,k≤r is the matrix
of ∂∗:C→C with respect to {xk∗}1≤k≤r,
and we have
[TABLE]
This implies that
[TABLE]
for any 1≤l,k≤r.
Hence x is a cycle.
Next, we prove that the homology class of x is non-zero.
It is obvious that ∑1≤k≤rxk∗⊗xk∈C∗⊗ΛC
is also a cycle.
Here, by using the chain isomorphisms Ξ and Γ in
Lemmas 2.18 and 2.19,
we can identify C∗⊗C with (C⊗C∗)∗
by (φ⊗y)(z⊗ψ)=φ(z)ψ(y)
(y,z∈C,φ,ψ∈C∗).
(In other words, ∑1≤k≤rxk∗⊗xk can be seen as a cocycle.)
Now, it follows from Lemma 2.8 that r is odd, and hence we have
[TABLE]
This implies that the homology class of x is non-zero.
∎
The following proposition is originally proved by Hom [4] in the case of knot complexes.
For a formal knot complex C,
the equalities ν+(C)=ν+(C∗)=0 holds
if and only if we have the Z2-filtered homotopy equivalence
[TABLE]
where A is a stabilizer.
The proof in [4] is naturally generalized to the case of formal knot complexes.
To prove Proposition 2.27, we use the following lemma.
Lemma 2.28**.**
The inequality ν+(C∗)≤m holds
if and only if the projection
p∗,0:H0(C)→H0(C/C{i≤−1 or j≤−m−1})
is injective.
Proof.
Let {xk}1≤k≤r be a filtered basis for C
and Φ denote the dual isomorphism induced by {xk}1≤k≤r.
We first prove the only-if-part.
Suppose that ν+(C∗)≤m.
Then there exists a homological generator φ∈C0∗
lying in
[TABLE]
In particular, we have
ε∘φ(C{i≤−1 or j≤−m−1})=ε∘φ(F−1Alex+F−m−1Alg)=0,
and ε∘φ is
decomposed as ε∘φ=φ∘p
where φ∈HomF(C{i≤−1 or j≤−m−1},F)
is a cocycle and p:C→C/C{i≤−1 or j≤−m−1}
is the projection.
Now, let x∈C0 be a homological generator.
Then we have φ(p(x))=(ε∘φ)(x)=1.
This implies that the homology class
[p(x)]∈H0(C/C{i≤−1 or j≤−m−1})
is non-zero, and hence
p∗,0 is injective.
Conversely, suppose that
p∗,0 is injective. Let x∈C0 be a homological generator,
and then we have p∗,0([x])=0.
In addition, dimF(C/C{i≤−1 or j≤−m−1})0
is finite, and hence we can take a finite F-basis for
H0(C/C{i≤−1 or j≤−m−1}) containing p∗,0([x]).
Thus, by using the identification
[TABLE]
we can take a cocycle
ψ∈HomF((C/C{i≤−1 or j≤−m−1})0,F)
whose cohomology class is the dual (p∗,0([x]))∗.
Moreover, the map
ε0 in Lemma 2.17 is bijective,
and hence we can take the inverse φ:=ε0−1(ψ∘p)∈C0∗.
Note that since ε∘φ(x)=ψ(p(x))=1,
the element φ∈C0∗ is a homological generator.
Moreover, the equalities
[TABLE]
hold, and hence φ lies in Φ(C/F−1Alg)∩Φ(C/F−m−1Alex)=C{i≤0,j≤m}∗.
This proves that ν+(C∗)≤m.
∎
The if-part immediately follows from Lemma 2.25.
To prove the only-if-part,
we will prove that if ν+(C)=ν+(C∗)=0, then there exists
a filtered basis {xk}1≤k≤r
such that C is decomposed into spanΛ{x1}⊕spanΛ{xk}2≤k≤r
as a chain complex.
In the situation, the restriction of ∂ on spanΛ{x1} is zero-map,
and hence it follows from Lemma 2.20 that spanΛ{x1} is a formal knot complex with
spanΛ{x1}≃Λ and spanΛ{xk}2≤k≤r
is a stabilizer.
Suppose that ν+(C)=ν+(C∗)=0, and let {xk}1≤k≤r be
a filtered basis for C.
By Lemma 2.7,
we may assume that gr(xk)=0 for k∈{1,…,r0} and gr(xk)=1 for
k∈{r0+1,…r}. Set r1:=r−r0 and yl:=xr0+l (1≤l≤r1).
Then, by the definition of ν+ and Lemma 2.28, there exists a homological generator
x=∑1≤k≤r0akxk∈C0 such that
x∈C{i≤0,j≤0}, and the homology class of p(x) is non-zero,
where p:C→C/C{i≤−1 or j≤−1} is the projection.
This implies that
•
if ak=0, then xk∈C{i≤0,j≤0}, and
•
there exists a number k∈{1,…,r0} with ak=0 and
xk∈/C{i≤−1 or j≤−1}.
As a consequence, we have k′∈{1,…,r0} such that ak′=0
and Alg(xk′)=Alex(xk′)=0.
Moreover, since the inequalities
[TABLE]
and
[TABLE]
hold for any k∈{1,…,r0} with ak=0,
it follows from Lemma 2.7
that {x}∪{xk}k=k′1≤k≤r0∪{yl}1≤l≤r1
is a filtered basis. We reorder {xk}k=k′1≤k≤r0
as {xk}2≤k≤r0.
Next, we will change {xk}2≤k≤r0 into {xk′}2≤k≤r0 so that
{x}∪{xk′}2≤k≤r0∪{yl}1≤l≤r1
is still a filtered basis and
∂({yl}1≤l≤r1)⊂spanF{xk′}2≤k≤r0.
Then, we can conclude that
both spanΛ{x} and
spanΛ({xk′}2≤k≤r0∪{yl}1≤l≤r1)
are subcomplexes, and this will complete the proof.
To obtain such {xk′}, we first note that
[TABLE]
is a basis for p(C0).
We reorder {xk}2≤k≤r0 so that
{px}∪{pxk}2≤k≤r0′
is a basis for p(C0). (Here r0′:=dimFp(C0).)
Let (akl)1≤l≤r11≤k≤r0′
be the matrix of p∘(∂∣C1):C1→p(C0) with respect to
the pair ({yl}1≤l≤r1,{pxk}2≤k≤r0′∪{px}),
i.e. p∘∂(yl)=∑1≤k≤r′−1aklpxk+1+ar′lpx.
Then we can replace {yl}1≤l≤r1 with
a basis {yl′}1≤l≤r1
so that the corresponding matrix
(akl′)1≤l≤r11≤k≤r0′
is in reduced column echelon form.
Here, since [px]=0 in H0(C/C{i≤−1 or j≤−1}),
px is not contained in p∘∂(C1) and
the last row of (akl′)1≤l≤r11≤k≤r0′
does not contain any leading coefficient.
In particular, if ar0′l′=0,
then there exists a number kl in {1,…,r0′−1}
such the kl-th row contains the l-th leading coefficient.
(Namely, akll′′=δll′, where δll′ is the Kronecker delta.)
Now, we define a set {xk′}2≤k≤r0 by
[TABLE]
Then, it follows from Lemma 2.7 that
{x}∪{xk′}2≤k≤r0∪{yl}1≤l≤r1
is a filtered basis.
Moreover,
the replacement of {pxk}2≤k≤r0′
with {pxk′}2≤k≤r0′ changes
(akl′)1≤l≤r11≤k≤r0′
so that the last row is zero vector.
This implies that
[TABLE]
and hence we have
[TABLE]
This completes the proof.
∎
Corollary 2.29**.**
Let C and C′ be formal knot complexes.
If ν+(C)=ν+(C∗)=0,
then ν+(C′⊗ΛC)=ν+(C′).
Proof.
By Proposition 2.27,
we have C≃Λ⊕A.
Here, Lemma 2.22 says
that C′⊗ΛA is a stabilizer,
and it is easy to show that
C′⊗Λ(Λ⊕A)≃C′⊕(C′⊗ΛA).
Therefore, by Lemma 2.25,
we have
[TABLE]
∎
Here we refer to the following theorem of Hom and Wu,
which is one of the most important facts
for obtaining concordance invariants from CFK∞.
For a knot K, the inequality ν+(CK)≤g4(K) holds.
In particular, if K is a slice knot, then
ν+(CK)=ν+((CK)∗)=0.
2.7. ν+-equivalence
Two elements [C],[C′]∈Kf are
ν+-equivalent* (and denoted [C]∼ν+[C′]
or C∼ν+C′)
if ν+(C⊗ΛC′∗)=ν+(C∗⊗ΛC′)=0.
Note that by Propositions 2.11 and 2.13,
the values
ν+(C⊗ΛC′∗) and ν+(C∗⊗ΛC′)
are independent of the choice of representatives.
Proposition 2.31**.**
The relation ∼ν+ is an equivalence relation on
Kf.
Proof.
The reflexivity (i.e. [C]∼ν+[C]) follows from Lemma 2.26.
The symmetry ([C]∼ν+[C′] if and only if [C′]∼ν+[C])
directly follows from the definition.
We prove the transitivity.
Suppose that [C1]∼ν+[C2] and [C2]∼ν+[C3].
Then, Proposition 2.24,
Lemma 2.26 and Corollary 2.29
imply
[TABLE]
Similarly, we can prove that
ν+(C1∗⊗C3)=0 holds.
∎
We call the equivalence class of a formal knot complex C under ∼ν+the ν+-equivalence class or ν+-class of C, and denote
it by [C]ν+.
Then, we can see that Hom’s stable homotopy theorem in [4] is naturally generalized to
formal knot complexes.
Two formal knot complexes C and C′ are
ν+-equivalent
if and only if we have the Z2-filtered homotopy equivalence
[TABLE]
where A,A′ are stabilizers.
Proof.
It follows from Lemma 2.25 and Proposition 2.27
that C∼ν+C′
if and only if
C⊗ΛC′∗≃Λ⊕A
where A is a stabilizer.
Thus, if C∼ν+C′, then there exist
stabilizers A1,A2 so that C∗⊗ΛC′≃Λ⊕A1
and C⊗ΛC∗≃Λ⊕A2, and we have
[TABLE]
Conversely,
if
C⊕A≃C′⊕A′,
then there exists a stabilizer A′′ so that
[TABLE]
and hence ν+(C⊗ΛC′∗)=ν+((C⊗ΛC′∗)⊕(A⊗ΛC′∗))=0.
Similarly, we have ν+(C∗⊗ΛC′)=0.
∎
Here, due to Theorem 2.30,
the ν+-class of CK can be seen
as a knot concordance invariant of K.
For a knot K, [K]ν+:=[CK]ν+ is
a knot concordance invariant of K.
Proof.
If two knots K and J are concordant, then both K#(−J∗) and (−K∗)#J
are slice knots. Thus, by Theorem 2.30, we have
[TABLE]
and
[TABLE]
∎
2.8. Formal knot concordance group
Now, the formal knot concordance groupCf is obtained as follows.
Proposition 2.34**.**
The quotient set Cf:=Kf/∼ν+
with product
[TABLE]
is an abelian group.
In particular,
the projection Kf↠Cf
is a monoid homomorphism.
Proof.
We first verify that the product is well-defined.
Suppose that [C]ν+=[C′′]ν+, and then
ν+(C⊗ΛC′′∗)=ν+(C∗⊗ΛC′′)=0.
Thus, it follows from Proposition 2.24 and
Lemma 2.26 that
[TABLE]
and
[TABLE]
Similarly, we can prove that if [C′]ν+=[C′′]ν+ then
[C⊗ΛC′]ν+=[C⊗ΛC′′]ν+.
Now, the commutativity immediately follows from
C⊗ΛC′≃C′⊗ΛC,
and obviously the projection Kf↠Cf is a monoid homomorphism.
∎
As a consequence, we have the following theorem, which is stated in
Section 1 as Theorem 1.7.
Theorem 2.35**.**
The map C→Cf:[K]c↦[CK]ν+ is
a well-defined group homomorphism.
As a consequence, we have the following commutative diagram:
[TABLE]
2.9. Partial order on Cf
In this subsection, we introduce a partial order on Cf,
which is a generalization of the partial order on Cν+
defined in [22].
Here, as a new observation, we give an interpretation of the ν+-equivalence
and the partial order on Cf using quasi-isomorphisms.
For two ν+ -classes [C]ν+,[C′]ν+∈Cf,
we denote [C]ν+≤[C′]ν+
if
the equality ν+(C⊗ΛC′∗)=0 holds.
Proposition 2.36**.**
The relation ≤ is a partial order on Cf.
Proof.
This immediately follows from Proposition 2.24,
Lemma 2.26
and the definition of ∼ν+.
∎
For two formal knot complexes, a chain map f:C→C′ over Λ is
a Z2-filtered quasi-isomorphism
if f is Z2-filtered, graded, and induces an isomorphism
f∗:H∗(C)→H∗(C′).
Then, the ν+-equivalence and the partial order on Cf
can be translated into the words of the existence of
Z2-filtered quasi-isomorphisms.
Theorem 2.37**.**
Two formal knot complexes C and C′ are ν+-equivalent
if and only if
there exist Z2-filtered quasi-isomorphisms
[TABLE]
Theorem 2.38**.**
Two ν+-classes [C]ν+ and [C′]ν+ satisfy
[C]ν+≥[C′]ν+ if and only if
there exists a Z2-filtered quasi-isomorphism
C→C′.
To prove these theorems, we first prove the following lemma.
Lemma 2.39**.**
Let C and C′ be formal knot complexes.
If there exists a Z2-filtered quasi-isomorphism
f:C→C′, then [C]ν+≥[C′]ν+.
Proof.
Note that under the hypothesis of the lemma,
f⊗idC∗:C⊗ΛC∗→C′⊗ΛC∗
is also a Z2-filtered quasi-isomorphism.
Moreover, by Lemma 2.26, we can take a homological generator x of
C⊗ΛC∗ lying in (C⊗ΛC∗){i≤0,j≤0}.
Now, we see that f⊗idC∗(x) is a homological generator
of C′⊗ΛC∗ lying in (C′⊗ΛC∗){i≤0,j≤0},
and hence ν+(C′⊗C∗)=0.
∎
The if-part directly follows from Lemma 2.39.
We prove the only-if-part. Suppose that C∼ν+C′.
Then, by Theorem 2.32,
we have a Z2-filtered homotopy equivalence map
[TABLE]
where A,A′ are stabilizers.
Let i:C↪C⊕A be the inclusion
and p:C′⊕A′↠C′ the projection.
Then, all of i,f′ and p are Z2-filtered quasi-isomorphisms,
and hence we have the Z2-filtered quasi-isomorphism
[TABLE]
Similarly, we can construct a Z2-filtered quasi-isomorphism
g:C′→C.
∎
The if-part coincides with Lemma 2.39.
We prove the only-if-part.
Suppose that [C]ν+≥[C′]ν+.
Then the equality
ν+(C′⊗ΛC∗)=0 holds, and hence
(C′⊗ΛC∗){i≤0,j≤0} contains a homological
generator x. Hence, if we define a Λ-linear map
[TABLE]
so that f(1)=x, then f is a Z2-filtered quasi isomorphism.
In addition, the map
[TABLE]
is also a Z2-filtered quasi isomorphism.
Moreover, since (C′⊗ΛC∗⊗ΛC)∼ν+C′,
Theorem 2.37 gives a Z2-filtered quasi isomorphism
[TABLE]
By combining these quasi isomorphisms, we obtained the desired quasi-isomorphism.
∎
When one wants to construct a Z2-filtered quasi-isomorphism concretely,
the following lemma is useful.
Lemma 2.40**.**
Let C and C′ be formal knot complexes and f:C→C′ be a chain map
over Λ such that
•
f* maps a homological generator C to that of C′, and*
•
for a filtered basis {xk}1≤k≤r of C and any k,
we have
[TABLE]
Then, f is a Z2-filtered quasi-isomorphism.
Proof.
Since
FjAlex(C)=spanF[U]{UAlex(xk)−jxk}1≤k≤r,
we have
[TABLE]
Similarly, we have f(FiAlg(C))⊂FiAlg(C′). Now, for any R∈CR(Z2),
we see that
[TABLE]
It is easy to see that f is a quasi-isomorphism.
∎
Set
Cν+:=Im(C→Cf:[K]c↦[CK]ν+).
Then Cν+ is naturally identified with a quotient group of C,
and the partial order on Cf induces a partial order on Cν+.
We note that the induced partial order coincides with
the order defined in author’s paper [22].
In particular, Proposition 1.5 in [22] is naturally generalized to Cf.
The partial order on Cf has the following properties:
(1)
For elements x,y,z∈Cf, if x≤y, then x+z≤y+z.
2. (2)
For elements x,y∈Cf, if x≤y, then −y≤−x.
On the other hand,
for the case of Cν+,
we also have the following geometric estimates.
(Here, full-twist operations are defined as follows.
Let K be a knot and D a disk in S3 which intersects K in its interior.
By performing (−1)-surgery along ∂D, we obtain a new knot J in S3 from K.
Let n=lk(K,∂D). Since reversing the orientation of D does not affect the result, we may assume that n≥0. Then we say that K is deformed into J by
a positive full-twist with n-linking, and call such an operation a full-twist operation.)
Suppose that a knot K is deformed into a knot J by
a positive full-twist with n-linking.
(1)
If n=0 or 1, then [J]ν+≤[K]ν+.
2. (2)
If n≥3, then [J]ν+≰[K]ν+.
In particular, if the geometric intersection number between K and D
is equal to n, then [J]ν+>[K]ν+.
2.10. Invariants of ν+-classes
In this subsection, we review the Vk-sequence [12],
the τ-invariant [13], the Υ-invariant [17]
and the Υ2-invariant [8]
as invariants of formal knot complexes under ν+-equivalence.
Here we use Z2-filtered quasi-isomorphisms to prove the invariance of them.
2.10.1. Vk-sequence
The Vk-sequence defined by Ni and Wu [12] is a family of
Z≥0-valued invariants which is parametrized by Z≥0.
Concretely, for a formal knot complex C and k∈Z≥0,
the value Vk(C) is defined by
[TABLE]
In particular, we have the equality
[TABLE]
Moreover, we can use homological generators to determine Vk(C).
Lemma 2.43**.**
For any k∈Z≥0, the equality
[TABLE]
holds.
Proof.
Denote the value of the right-hand side of the equality in Lemma 2.43
by Vk′(C). We first prove that Vk(C)≥Vk′(C).
Since H∗(C{i≤0})≅F[U] and the map
i∗:H∗(C{i≤0,j≤k})→H∗(C{i≤0})
is a F[U]-linear map, if Imi∗,2m=H2m(C{i≤0})
then Imi∗,2n=H2n(C{i≤0}) for any n≤m.
This implies that
[TABLE]
is surjective. Moreover, the map
i∗,n:Hn(C{i≤0})→Hn(C)
is an isomorphism for any n≤0. Consequently, we see that
there exists a cycle x∈C−2Vk(C) lying in C{i≤0,j≤k}
such that the homology class [x]∈H−2Vk(C)(C) is non-zero.
This implies that U−Vk(C)x∈C0 is a homological generator lying
in C{i≤Vk(C),j≤k+Vk(C)}.
Therefore, we have Vk(C)≥Vk′(C).
Conversely, since C{i≤Vk′(C),j≤k+Vk′(C)} contains a homological generator
x, the cycle UVk′(C)x∈C−2Vk′(C) is lying in C{i≤0,j≤k}.
This implies that the map
[TABLE]
is surjective, and hence Vk(C)≤Vk′(C).
∎
Now, we can easily see that Vk is a well-defined map on Cf and preserve the
partial order.
Corollary 2.44**.**
If [C]ν+≤[C′]ν+, then Vk(C)≤Vk(C′) for any k≥0.
In particular, Vk is a well-defined map Cf→Z≥0.
Proof.
Suppose that [C]ν+≤[C′]ν+, and then we have a Z2-filtered
quasi-isomorphism f:C′→C. Here, by using Lemma 2.43,
we can take a homological generator x∈C′ lying in
C{i≤Vk(C′),j≤k+Vk(C′)}′.
Then, f(x) is a homological generator of C lying in
C{i≤Vk(C′),j≤k+Vk(C′)}. This completes the proof.
∎
In addition, we also have the following properties of Vk.
Corollary 2.45**.**
For any k∈Z≥0, we have
[TABLE]
In particular, for any 0≤k≤ν+(C), the inequality Vk(C)+k≤ν+(C) holds.
Proof.
The first assertion immediately follows from the fact that
[TABLE]
Next, for any 0≤k≤ν+(C), we see that
[TABLE]
This completes the proof.
∎
Moreover, we have a connected sum inequality for Vk.
(For knot complexes, it is given in [1].)
Corollary 2.46**.**
For any formal knot complexes C,C′ and k,k′∈Z≥0, we have
[TABLE]
Proof.
By Lemma 2.43, we have a homological generator
x∈C (resp. x′∈C′) which is lying in
C{i≤Vk(C),i≤k+Vk(C)}
(resp. C{i≤Vk′(C′),i≤k+Vk′(C′)}).
This implies that x⊗x′ is a homological generator of C⊗ΛC′
lying in
[TABLE]
This completes the proof.
∎
For the case of knot complexes, Vk(K):=Vk(CK) is an important invariant
because it completely determines all correction terms of all positive Dehn surgeries along K.
To state the fact precisely, we fix several notations.
For coprime integers p,q>0, let Sp/q3(K) denote the p/q-surgery along K.
Note that there is a canonical identification between the set
of Spinc structures over Sp/q3(K)
and {i∣0≤i≤p−1}. This identification can be
made explicit by the procedure in [19, Section 4, Section 7].
Let d(Sp/q3(K),i) denote the correction term of Sp/q3(K)
with the i-th Spinc structure (0≤i≤p−1).
holds,
where O denotes the unknot and ⌊⋅⌋ is the floor function.
2.10.2. τ-invariant
Let C be a formal knot complex.
Define
[TABLE]
and
[TABLE]
for any m∈Z.
Then we see H∗(C)=H0(C)≅F, and {Fm}m∈Z is an increasing sequence of subcomplexes on C, i.e. a Z-filtration on C.
We call a cycle x∈C a
hat-generator
if x is homogeneous with gr(x)=0 and the homology class [x]∈H0(C)
is non-zero. We define the τ-invariant of C by
[TABLE]
We can use homological generators to determine τ(C) like Vk(C).
Lemma 2.48**.**
The equality
[TABLE]
holds.
Proof.
Denote the value of right-hand side of the equality in Lemma 2.48
by τ′(C). We first prove that τ(C)≥τ′(C).
By the definition of τ(C), there exists a chain
x∈C{i≤−1}∪{i≤0,j≤τ(C)} such that
p(x)∈Fτ(C) is a hat-generator,
where p:C{i≤0}→C is the projection.
Moreover, since the induced map
p∗,0:H0(C{i≤0})→H0(C) is an isomorphism,
there exists a 0-chain y∈C{i≤−1} such that
∂y=∂x. In particular, x−y is a homological generator of C
lying in C{i≤−1}∪{i≤0,j≤τ(C)}. (Note that
p∗,0([x−y])=[p(x−y)]=[p(x)]=0.)
Therefore, we have τ(C)≥τ′(C).
Conversely, since C{i≤−1}∪{i≤0,j≤τ′(C)} contains
a homological generator x′ and the above map p∗,0 is an isomorphism,
p(x′) is a hat-generator lying in Fτ′(C). This gives τ(C)≤τ′(C).
∎
Now, by the same arguments as the proof of Corollary 2.44,
we have the following.
Corollary 2.49**.**
If [C]ν+≤[C′]ν+, then τ(C)≤τ(C′).
In particular, τ is a well-defined map Cf→Z.
In addition, τ is related to ν+ as follows.
Corollary 2.50**.**
The inequality τ(C)≤ν+(C) holds.
Proof.
This follows from
C{i≤0,j≤ν+(C)}⊂C{i≤−1}∪{i≤0,j≤ν+(C)}.
∎
One of the most important property of τ-invariant
is the following additivity.
Proposition 2.51**.**
τ* is a group homomorphism as a map Cf→Z.*
Proof.
Let C and C′ be formal knot complexes.
Then we can see from Proposition 2.11 that
the Z-filtered homotopy equivalence
[TABLE]
holds, where p:FC×C′↠C⊗FC′
is the projection.
Next, let x∈Fτ(C) (resp. x′∈Fτ(C′)′) a hat-generator.
Then, in a similar way to the proof of Proposition 2.27, we have the Z-filtered
homotopy-equivalence
[TABLE]
where A and A′ are acyclic Z-filtered chain complexes.
Consequently, the Z-filtered homotopy equivalence
[TABLE]
holds for some acyclic Z-filtered chain complex A′′, and this implies that
τ(C⊗ΛC′)=τ(C)+τ(C′).
∎
As a consequence, we have the original τ-invariant for knots.
The map [K]c↦τ(CK) is a group homomorphism as a map
C→Z.
2.10.3. Υ-invariant
For any t∈[0,2] and s∈R, the set
[TABLE]
is a closed region. Hence, if we denote CRt(s) by Fst,
then we have a R-filtration {Fst}s∈R of C.
We define
[TABLE]
and
[TABLE]
Remark**.**
This definition of Υ is due to Livingston [10] rather than
the original one [17].
Since there exist finitely many homological generators of C and their
Alexander and algebraic filtrations are finite, υC(t) and ΥC(t)
are finite values. In the same way as Vk and τ,
we can prove the following proposition.
Proposition 2.53**.**
If [C]ν+≤[C′]ν+, then ΥC(t)≥ΥC′(t)
for any t∈[0,2].
In particular, Υ(t):[C]ν+↦ΥC(t) is a well-defined map
Cf→R for any t∈[0,2].
In addition, we can see Υ as a linear approximation of Vk
in the following sense.
Proposition 2.54**.**
For any t∈[0,2] and k∈Z≥0,
the inequality
[TABLE]
holds. In particular, ΥC(t)≥−ν+(C)t holds.
Proof.
This follows from
C{i≤Vk(C),j≤k+Vk(C)}⊂C{(1−2t)i+2tj≤Vk(C)+2tk}.
∎
Moreover, The additivity of Υ(t) is also obtained in the same way as τ.
Proposition 2.55**.**
For any t∈[0,2], Υ(t) is a
group homomorphism as a map Cf→R.
We can generalize the following properties of the original Υ-invariant
to formal knot complexes. The proof is similar to [10, Theorem 8.1].
Proposition 2.56**.**
For any formal knot complexes C, the following properties hold.
(1)
The map ΥC:[0,2]→R,t↦ΥC(t)
is a continuous piecewise linear function.
2. (2)
For any regular point t of ΥC and filtered basis
{xk}1≤k≤r,
there exists an element xl∈{xk}1≤k≤r with gr(xl)=0
such that
[TABLE]
at any point t′ nearby t.
3. (3)
Let t be a singular point of ΥC and
{xk}1≤k≤r a filtered basis.
Then there exists two elements xl,xl′∈{xk}1≤k≤r with
gr(xl)=gr(xl′)=0
such that
•
Alex(xl)−Alex(xl′)=(1−t2)(Alg(xl)−Alg(xl′)),
•
the equality
[TABLE]
holds at any point t′ nearby t satisfying t′<t, and
•
the equality
[TABLE]
holds at any point t′ nearby t satisfying t′>t.
As a consequence of the above arguments, we have the following corollaries.
Here, PL([0,2],R) denotes the set of continuous piecewise linear functions on [0,2].
Corollary 2.57**.**
The map Υ:[C]ν+↦ΥC is a group homomorphism
Cf→PL([0,2],R).
Corollary 2.58**.**
The map [K]c↦ΥCK is a group homomorphism
C→PL([0,2],R).
Here we mention that the gradient of ΥC nearby [math] is equal to −τ(C).
The proof is the same as [10, Theorem 14.1].
Proposition 2.59**.**
For any sufficiently small t>0, we have
ΥC(t)=−τ(C)t.
2.10.4. Υ2-invariant
Let C be a formal knot complex, {xk}1≤k≤r a filtered basis
and {C(i,j)} the induced decomposition of C.
Define the support of {C(i,j)} by
[TABLE]
In addition, consider the support line forFst by
[TABLE]
Now, for any t∈[0,2], set
[TABLE]
Then, we see that Pt=∅ for any t.
Moreover, from Proposition 2.56, we have the following proposition.
Proposition 2.60**.**
The following assertions hold:
(1)
For any t∈[0,2] and small δ>0, the
intersection Pt∩Pt−δ
(resp. Pt∩Pt+δ)
has exactly one point. (We denote these points by pt− and pt+, respectively.)
2. (2)
The function ΥK has a singularity at t
if and only if pt−=pt+.
In light of this proposition, for small δ>0, we set
[TABLE]
If Zt−(C)∩Zt+(C)=∅,
then for any s∈[0,2], we define
[TABLE]
Now, we can define the Υ2-invariant of C as
[TABLE]
From the view point of Z2-filtered quasi isomorphism, we have
the following inequality.
Proposition 2.61**.**
Fix t∈(0,2). If [C]ν+≤[C′]ν+ and ΥC(t′)=ΥC′(t′)
for any point t′ nearby t, then ΥC,t2(s)≥ΥC′,t2(s)
for any s∈[0,2].
Proof.
Take δ>0 sufficiently small so that Propsition 2.60
holds at given t for both C and C′.
Let z′±∈Zt±(C′) such that
[TABLE]
and f:C′→C a Z2-filtered quasi isomorphism.
Then, since υC(t′)=υC′(t′)
for any point t′ nearby t,
we see f(z′±)∈Zt±(C).
Now, we have the equalities
[TABLE]
as elements of H0(FυC(t)r(C)+FυC′,t2(s)s(C)).
Hence, if Zt−(C)∩Zt+(C)=∅,
then C′ also satisfies Zt−(C′)∩Zt+(C′)=∅
and
we have the inequality
[TABLE]
which gives the desired inequality. Otherwise, ΥC,t2(s)=∞,
and hence the desired inequality obviously holds.
∎
As a corollary, we have the invariance of Υ2.
(Note that Υ2 is originally given as an invariant of formal knot complexes
in [8].)
For any t∈(0,2) and s∈[0,2],
Υt2(s):[C]ν+↦ΥC,t2(s)
is a well-defined map Cf→R∪{∞}.
In particular, ΥK,t2(s):=ΥCK,t2(s)
is a knot concordance invariant.
We also mention the following sub-additivity of ΥC,t2(t).
For any formal knot complexes C,C′ and t∈(0,2), we have
[TABLE]
3. Geometric estimates
In this section, we prove the following theorem.
Theorem 1.5**.**
For any knot K, we have
[TABLE]
To prove the theorem, we consider replacing a given knot K several times.
We start with the following lemma.
Lemma 3.1**.**
For any knot K,
there exists a knot K′ concordant to K which bounds a ribbon surface with genus g4(K).
Proof.
Let F be a surface in B4≅(S3×[0,1])/(S3×{1}) with genus g4(K) and ∂F=K⊂S3×{0}.
Then, a similar argument to [21, Lemma2.1]
shows that F can be isotoped to a surface F′ in B4 such that
the composition f:F′↪(S3×[0,1])/(S3×{1})↠p2[0,1] is a Morse function, and f satisfies
(1)
all births happen at time 61 (we denote the number of births by b),
2. (2)
b saddles happen at time 62,
3. (3)
the time 63 is a regular value and f−1(63) is connected,
4. (4)
the remaining saddles happen at time 64, and
5. (5)
all deaths happen at 65.
In particular, we see that f−1([0,63]) is a (ribbon) concordance from K to
K′:=f−1(63), and f−1([63,1]) is a ribbon surface in
(S3×[63,1])/(S3×{1})≅B4 whose boundary is K′ and genus is g4(K). This completes the proof.
∎
Next, by using full-twists, we construct a surface embedded in S3.
Lemma 3.2**.**
If a knot K bounds a genus g ribbon surface, then there exists a
knot K′ with genus g
which obtained from K only by adding positive full-twists with 1-linking.
Proof.
Suppose that K bounds a genus g ribbon surface F with n ribbon singularities.
Then, for proving the lemma, it suffices to find a positive full-twist with 1-linking deforming K into a knot K′
which bounds a genus g ribbon surface with n−1 ribbon singularities.
Let Σg be an abstract genus g surface with ∂Σg≅S1,
and f:Σg→S3 an immersion with f(Σg)=F.
Choose a ribbon singularity b on F. Then
f−1(b) consists of two arcs in Σg, one of which is properly embedded and the other is lying in IntΣg. Denote the arc in IntΣg by b, and take an arc a
in Σg
such that Inta avoids the preimage of all ribbon singularities on F, and
one end of a is in ∂b and the other is in ∂Σg.
Then f(a) is an arc in F which connects b to ∂F, and Intf(a) avoids all singularities on F. Thus, we can take a (small) tubular neighborhood N of f(a)∪b
such that (N,F∩N) is diffeomorphic to the pair of the 3-ball and the immersed surface
shown in Figure 2.
Now, we take a twisting disk D as shown in the right-hand side of Figure 3.
After adding a positive full-twist along D, we have a new ribbon surface F′ which coincides
with F in S3∖N, and (N,F′∩N) is diffeomorphic to the pair of the 3-ball and the embedded surface shown in the right-hand side of Figure 3. By the construction, it is obvious that K′:=∂F′
is obtained from K by a positive full-twist with 1-linking, and
F′ is a genus g ribbon surface with n−1 ribbon singularities.
This completes the proof.
∎
For m,n∈Z,
let Km,n denote the (m,n)-twist knot, whose diagram is shown in Figure 4.
Then, the last replacement is stated as follows.
Lemma 3.3**.**
Any genus g knot is deformed into
Km1,n1#⋯#Kmg,ng only by adding positive full-twists
with [math]-linking, where mi,ni∈Z>0 (for all i∈{1,…,g}).
Proof.
Let K be a genus g knot
and F a genus g surface with boundary K.
By an isotopy, we can assume that F is of the form of Figure 5,
where L is obtained from a string link (with 4g strings) by parallelizing the string link with some framings. (The framings are characterized by the choice of {m1′,n1′,…,mg′,ng′}.)
Then, as shown in Figure 6, positive full-twists with 0-linking can realize both directions of pass moves with framings changing, and hence such full-twists can deform F into a surface F′ with new framings {m1,n1,…,mg,ng}, which is shown in Figure 7.
Moreover, by
adding positive full-twists with 0-linking as shown in Figure 8, we may assume that
all mi,ni are positive. Here it is obvious that the boundary of F′ is
Km1,n1#⋯#Kmg,ng, and this fact completes the proof.
∎
Here we note that all Km,n are 2-bridge knots and hence alternating knots.
For alternating knots, the following strong classification theorem of ν+-classes
follows from [20, Section 3.1].
Fix a knot K. Then,
Lemma 3.1 provides a knot K′ such that [K′]ν+=[K]ν+ and
K′ bounds a ribbon surface with genus g4(K).
Moreover, it follows from Lemma 3.2
and Lemma 3.3
that there exists a sequence of finitely many positive full-twists with 0 or 1-linking
which deforms K′ into Km1,n1#⋯#Kmg4(K),ng4(K)
for some mi,ni∈Z>0 (i∈{1,…,g4(K)}).
Therefore, by Theorem 2.42 and Lemma 3.5,
we have
[TABLE]
Since g4(−K∗)=g4(K), we also have
[TABLE]
This completes the proof.
∎
4. Algebraic estimates
In this section, we establish several algebraic estimates for the ν+-classes,
and prove Theorem 1.2 and Theorem 1.6.
4.1. Genus of a formal knot complex
We first define the genus of formal knot complexes.
4.1.1. Maximal and minimal degrees
For a formal knot complex C, set
[TABLE]
and
[TABLE]
(For the definition of {Fm}m∈Z, see Subsection 2.10.2.)
Let {xk}1≤k≤r be a filtered basis for C.
The finiteness of the above values follows from the following lemma.
Lemma 4.1**.**
The equalities
[TABLE]
and
[TABLE]
hold.
Proof.
From the definition of {Fm}m∈Z, we can see that
[TABLE]
This completes the proof.
∎
Corollary 4.2**.**
The equalities
[TABLE]
hold.
Proof.
As shown in the proof of Proposition 2.13,
we can take a filtered basis {xk∗}1≤k≤r
such that
[TABLE]
This completes the proof.
∎
Moreover, about the decomposition {C(i,j)}(i,j)∈Z2 induced by
a filtered basis {xk},
we have the following lemma.
Lemma 4.3**.**
The support
{(i,j)∣C(i,j)=0}
is contained in the set
[TABLE]
Proof.
If Ulxk is lying in C(i,j), then
[TABLE]
Therefore, by Lemma 4.1, we have mdeg(C)≤j−i≤Mdeg(C).
∎
For a coordinate (k,l)∈Z2, set
[TABLE]
and then R(k,l)∈CR. For any subset S⊂Z2,
define the closure of S by
[TABLE]
Then we also have cl(S)∈CR(Z2).
In addition, the equality
[TABLE]
holds.
For any R∈CR(Z2) and m,M∈Z with m≤M, define
[TABLE]
Then, as a corollary of Lemma 4.3, we have the following.
Corollary 4.4**.**
For any formal knot complex C and R∈CR(Z2), the equality
[TABLE]
holds.
Proof.
Since R⊃cl(Smdeg(C),Mdeg(C)R),
obviously we have CR⊃Ccl(Smdeg(C),Mdeg(C)R).
Next we prove the converse. Fix a filtered basis {xk}1≤k≤r
and denote the induced decomposition by {C(i,j)}.
By Lemma 2.9,
it suffices to show that for any (i,j)∈R∖cl(Smdeg(C),Mdeg(C)R),
the equality C(i,j)=0 holds.
Indeed,
for any such coordinate (i,j), at least one of the
inequalities
[TABLE]
holds.
Therefore, it follows from Lemma 4.3 that C(i,j)=0.
∎
4.1.2. Genus of a formal knot complex
Now we define the genus of a formal knot complex C by
[TABLE]
Then it is obvious that g(C)≥0, and Corollary 4.2 gives
g(C∗)=g(C).
Moreover, for knot complexes, we have the following.
Moreover,
by definition, we have −g(C)≤mdeg(C)≤Mdeg(C)≤g(C).
Hence Corollary 4.4 gives the following.
Corollary 4.6**.**
For any formal knot complex C and R∈CR(Z2), the equality
[TABLE]
holds.
The following lemma is useful for reducing CR
in concrete situations.
Lemma 4.7**.**
The following assertions hold:
(1)
For any k∈Z, we have C{i≤k}=CR(k,g(C)+k).
2. (2)
For any l∈Z, we have C{j≤l}=CR(g(C)+l,l).
Proof.
Here we verify the assertion (1).
For any k∈Z,
we see
[TABLE]
Therefore, we have {i≤k}⊃(R(k,g(C)+k))⊃cl(S−g(C),g(C){i≤k}),
and hence Corollary 4.6 gives C{i≤k}=CR(k,g(C)+k).
Similarly, we can verify the assertion (2).
∎
4.2. Comparison with [(T2,2g+1)∗]ν+
For g∈Z≥0, let T2,2g+1 be the (2,2g+1)-torus knot.
These knots are alternating knots such that σ(T2,2g+1)=−2g,
and hence it follows from Theorem 3.4 that
[T2,2g+1]=g[T2,3].
In this subsection, we consider comparing ν+-classes with [(T2g+1)∗]ν+.
First, we recall that the knot complex
C(T2,2g+1)∗ has a filtered basis
[TABLE]
satisfying:
•
gr(ak)=0 and gr(bl)=−1.
•
(Alg(ak),Alex(ak))=(−g+k,−k) and (Alg(bl),Alex(bl))=(−g+l,−l−1).
•
∂ak=bk−1+bk and ∂bl=0, where b−1=bg=0.
Here we note that a:=a0+⋯+ag is a unique homological generator of
C(T2,2g+1)∗.
For any g∈Z≥0, define
[TABLE]
Then we have the following sufficient condition for satisfying the inequality
[C]ν+≤[(T2,2g+1)∗]ν+.
Proposition 4.8**.**
For any formal knot complex C, if CRg contains a homological generator,
then the inequality
[TABLE]
holds.
Proof.
Fix a filtered basis and denote the induced decomposition
by {C(i,j)}.
Define the subsets Sk⊂Z2 (k=0,1,…,g) by
[TABLE]
and
[TABLE]
for 1≤k≤g.
Then Rg=⨿0≤k≤gSk,
and hence we can uniquely decompose a homological generator z∈CRg
into a linear combination
z=∑k=0gzk, where zk∈⨁(i,j)∈SkC(i,j).
We denote yl:=∂(z0+…+zl) for any 0≤l≤g−1.
Claim 1**.**
yl* is lying in CR(−g+l,−l−1).*
Proof.
Since z is a cycle, we see
yl=∂(z0+⋯+zl)=∂(zl+1+⋯+zg).
Moreover, since the relations
[TABLE]
and
[TABLE]
hold, we have
yl∈C⋃0≤k≤lR(−g+k,−k)∩C⋃l+1≤k≤gR(−g+k,−k). Here, Lemma 2.9
gives
[TABLE]
∎
Now, we define a Λ-linear map f:C(T2,2g+1)∗→C
by
[TABLE]
Then we can check that f is a chain map over Λ.
(Notice that ∂zk=∂(z0+⋯+zk−1)+∂(z0+⋯+zk)=yk−1+yk.)
Moreover, by Claim 1, we have
[TABLE]
and
[TABLE]
In addition, f(a)=f(a0+⋯+ag)=z0+⋯+zg=z.
Now, Lemma 2.40 proves that f is a
Z2-filtered quasi-isomorphism.
∎
4.3. An estimate of genus one complexes
Here, we consider an estimate for genus one formal knot complexes.
Theorem 4.9**.**
Let C be a formal knot complex with g(C)=1.
(1)
If τ(C)=1, then [C]ν+≥[T2,3]ν+.
2. (2)
If τ(C)=0, then [C]ν+=0.
3. (3)
If τ(C)=−1, then [C]ν+≤−[T2,3]ν+.
Proof.
By Lemma 2.48, we have a homological generator
lying in C{i≤−1}∪R(0,τ(C)).
Moreover, Lemma 2.10 and Lemma 4.7 imply that
[TABLE]
As a result,
we have a homological generator in CR(−1,0)∪R(0,τ(C)).
First, suppose that τ(C)=0. Then
CR(−1,0)∪R(0,τ(C))=CR(0,0).
This proves ν+(C)=0. Moreover, since τ(C∗)=−τ(C)=0 and
g(C∗)=g(C)=1, we also have
ν+(C∗)=0. Therefore, the assertion (2) holds.
Next, suppose that τ(C)=−1. Then
CR(−1,0)∪R(0,τ(C))=CR(−1,0)∪R(0,−1)=CR1.
Therefore, it follows from Proposition 4.8
that [C]ν+≤[(T2,3)∗]=−[T2,3], and the assertion (3) holds.
Finally, the assertion (1) follows from the assertion (3) and the fact
that τ(C∗)=−τ(C)=−1 and [C∗]ν+=−[C]ν+.
∎
Now we can prove the main theorem.
Theorem 1.2**.**
For any knot K with g(K)=1,
we have
[TABLE]
In other words, any genus one knot is ν+-equivalent
to one of the trefoil, its mirror and the unknot.
Proof.
Let K be a genus one knot.
Then, by Theorem 1.5, we have
[TABLE]
Moreover, by Theorem 4.5, we can take a knot complex CK
with g(CK)=1.
Hence, Theorem 4.9 gives
[TABLE]
This completes the proof.
∎
4.4. An estimate using Υ
Here we show an estimate which is obtained by using Υ.
Theorem 4.10**.**
If ΥC(1)=g(C), then
[C]ν+≤−g(C)[T2,3]ν+.
Proof.
By the definition of Υ,
we have a homological generator lying in
C{i+j≤−g(C)}.
Here, we note that
As a result, we have a homological generator in CRg(C).
Therefore, Proposition 4.8 proves that
[C]ν+≤[(T2,2g(C)+1)∗]ν+=−g(C)[T2,3]ν+.
∎
Now we can prove the following discriminant.
Theorem 1.6**.**
The equality [K]ν+=−g(K)[T2,3]ν+ holds
if and only if ΥK(1)=g(K).
Proof.
The only-if-part obviously holds.
We prove the if-part.
For any knot K, by Theorem 1.5, we have
[TABLE]
Moreover, by Theorem 4.5, we can take a knot complex CK
with g(CK)=g(K).
Hence, if ΥK(1)=g(K), then Theorem 4.10 gives
[TABLE]
This completes the proof.
∎
5. New concordance invariants
In this section, we discuss new invariants {Gn} of ν+-classes whose values
are finite subsets of CR(Z2).
5.1. The invariants G0 and G0
As seen in Subsection 2.10,
many invariants introduced in previous work can be translated into the words
of closed regions containing a homological generator. From the view point,
it is natural to consider the universal set
[TABLE]
In fact, it behaves very naturally in terms of filtered quasi-isomorphism.
Theorem 5.1**.**
If [C]ν+≤[C′]ν+, then G0(C)⊃G0(C′).
Proof.
By assumption, we have a Z2-filtered quasi-isomorphism
f:C′→C.
Therefore, for any element R∈G0(C′) and a homological generator
x∈CR′, we see that
CR also contains a homological generator f(x), and hence
R∈G0(C).
∎
As a corollary, we have the invariance of G0.
Here P(CR(Z2)) denotes the power set of CR(Z2).
Corollary 5.2**.**
G0(C)* is invariant under ν+-equivalence. In particular,*
[TABLE]
is a well-defined map
Cf→P(CR(Z2)).
By definition, G0(C) obviously has the following property.
Proposition 5.3**.**
For any R∈G0(C) and R′∈CR(Z2), if R⊂R′,
then R′∈G0(C).
In particular, we see that G0(C) is an infinite set.
To extract an essential part of G0,
we consider the minimalization of G0.
For a subset S⊂CR(Z2),
an element R∈S is minimal in S
if it satisfies
[TABLE]
Define the map
[TABLE]
by
[TABLE]
Now we define G0(C) by
[TABLE]
The invariance of G0(C) under
∼ν+ immediately follows from
Corollary 5.2.
Here, for referring later, we prove the following lemma.
Lemma 5.4**.**
Let S⊂CR(Z2) be a non-empty finite subset.
Then, for any R∈S, there exists an element
R′∈minS with R′⊂R.
In particular, minS is non-empty.
Proof.
We prove the lemma by the induction of the order of S.
If ∣S∣=1, then minS=S, and the assertion obviously holds.
Assume that for any subset of CR(Z2) with order n, the assertion holds.
Let S⊂CR(Z2) be a subset
with order n+1. If any element of S is minimal in S,
then the assertion holds for S.
Suppose that there exist elements
R,R′⊂S such that R′⊊R.
Then, since S∖{R} has order n, the assertion holds for
S∖{R}. In particular, we have an element R′′∈min(S∖{R})
with R′′⊂R′. Here we note that
R⊂R′′, and hence R′′∈minS.
Moreover, we have R′′⊂R′⊂R.
This implies that the assertion holds for S,
and completes the proof.
∎
5.2. Finiteness of G0
In this subsection, we show that G0(C) is a finite set for any formal knot complex C.
5.2.1. The region of a chain
For a non-zero element p=p(U)∈Λ,
denote the lowest degree of p by l(p).
Let C be a formal knot complex, and
{xk}1≤k≤r a filtered basis for C.
For any non-zero chain x=∑1≤k≤rpk(U)xk,
we define the region ofx as
[TABLE]
Then we see that Rx∈CR(Z2) and x∈CRx.
The following lemma implies that Rx does not depend on the choice of {xk}.
Lemma 5.5**.**
The equality
[TABLE]
holds.
In particular, x∈CR if and only if Rx⊂R.
Proof.
It is obvious that Rx⊃⋂R∈CR,x∈CRR.
We prove the converse. Let {C(i,j)} be the decomposition of C
induced by {xk}, and take R∈CR(Z2) with x∈CR.
Then, since CR=⨁(i,j)∈RC(i,j)
and
[TABLE]
we see that
[TABLE]
for any k∈{1,…,r} with pk(U)=0.
This completes the proof.
∎
Lemma 5.6**.**
For any Z2-filtered chain map f:C→C′ and x∈C,
we have Rf(x)⊂Rx.
and call x∈gen0(C;R)a realizer of R.
Notice that since dimFC0<∞,
C has finitely many homological generators, and hence
both G0′(C) and G0′(C) are finite and non-empty.
Therefore, the following theorem implies the finiteness
and non-emptiness of G0(C).
Theorem 5.7**.**
The equality G0(C)=G0′(C) holds.
Proof.
We first prove G0(C)⊃G0′(C).
Note that since x∈CRx for any homological generator x,
we have G0(C)⊃G0′(C).
Take Rx∈G0′(C), and suppose that
R∈G0(C) and R⊂Rx.
Then, there exists a homological generator x′ in CR,
and hence Lemma 5.5 implies
Rx′⊂R⊂Rx.
Here, since Rx′∈G0′(C) and Rx is minimal in G0′(C),
we have Rx′=R=Rx. This proves Rx∈G0(C), and hence
G0(C)⊃G0′(C).
Next we prove G0(C)⊂G0′(C).
For a given element R∈G0(C),
we first need to prove that
R∈G0′(C). Here, in a similar way to the above arguments, we see that
there exists a homological generator x such that Rx⊂R.
Moreover, since Rx is also in G0(C) and R is minimal in G0(C),
we have R=Rx∈G0′(C).
Now, the minimality of R in G0′(C) immediately follows from
the minimality in G0(C).
Therefore, we have R∈G0′(C), and hence G0(C)⊂G0′(C).
∎
As a corollary, we have the following useful property of G0(C).
Corollary 5.8**.**
For any formal knot complex C and R∈CR(Z2),the following holds:
[TABLE]
Proof.
By the definition of G0(C), there exists a homological generator x∈C
with Rx⊂R. Moreover, since Rx∈G0′(C) and
G0′(C) is a non-empty finite set, Lemma 5.4
gives an element R′∈G0′(C)=G0(C)
with R′⊂Rx⊂R.
∎
Here we also mention the relationship of G0(C) to the partial order on Cf.
Proposition 5.9**.**
If [C]ν+≤[C′]ν+, then for any R′∈G0(C′), there
exists an element R∈G0(C) with R⊂R′.
Proof.
For any R′∈G0(C′), Theorem 5.1 shows R′∈G0(C).
Now, by Corollary 5.8,
we have an element R∈G0(C) with R⊂R′.
∎
5.3. Higher invariants Gn
Here, we discuss higher invariants.
5.3.1. The secondary invariant G1
For a formal knot complex C, suppose that
G0(C) has distinct two elements R1 and R2.
Under the hypothesis, we define the secondary invariant
G1(C;R1,R2) as follows.
First, set
[TABLE]
and
[TABLE]
Then we define G1(C;R1,R2) by
[TABLE]
Here, for R∈G1(C;R1,R2), we also define the realizers of R by
[TABLE]
Note that the above notions are independent of the order of {R1,R2}.
Lemma 5.10**.**
G1(C;R1,R2)* is a non-empty finite set.*
Proof.
Take an arbitrary realizer zi∈gen0(C;Ri) for each i=1,2.
Then we see that 0=[z1]=[z2]∈H0(C)≅F,
and hence there exists a 1-chain x∈C1 such that ∂x=z1+z2.
Moreover, dimF(C1)<∞.
These facts shows that gen1(C;R1,R2) is non-empty and finite.
Combining this fact with Lemma 5.4,
we see that
G1(C;R1,R2) is non-empty and finite.
∎
Theorem 5.11**.**
Suppose that [C]ν+≤[C′]ν+ and
G0(C)∩G0(C′) has distinct two elements R1 and R2.
Then, for any R′∈G1(C′;R1,R2), there exists an element
R∈G1(C;R1,R2) with R⊂R′.
Proof.
Take zi∈gen0(C′;Ri) (i=1,2) and x∈gen1(C′;R1,R2;R′) such that
∂x=z1+z2. Let f:C′→C be a Z2-filtered quasi-isomorphism.
Then we see from the assumption and Lemma 5.6 that
[TABLE]
and
[TABLE]
Moreover,
Ri is minimal in G0′(C), and hence we have
Rf(zi)=Ri.
In particular, f(zi)∈gen0(C;Ri).
Here, note that
[TABLE]
and hence f(x)∈gen1(C;R1,R2) and Rf(x)∈G1(C;R1,R2).
Now, Lemma 5.4 and Lemma 5.6 give
an element R∈G1(C;R1,R2) with
[TABLE]
∎
Corollary 5.12**.**
For any [C]ν+∈Cf and distinct two elements
R1,R2∈G0(C),
G1(C;R1,R2)∈P(CR(Z2))
is an invariant of the ν+-class [C]ν+.
Proof.
Suppose that [C]ν+=[C′]ν+.
Then, since G0(C)=G0(C′),
we have R1,R2∈G0(C)∩G0(C′).
Let R∈G1(C;R1,R2). Since [C]ν+≥[C′]ν+,
Theorem 5.11 gives
R′∈G1(C′;R1,R2) with R′⊂R.
Moreover, since [C]ν+≤[C′]ν+,
we also have
R′′∈G1(C;R1,R2) with R′′⊂R′⊂R.
Here, since R is minimal in G1′(C;R1,R2), we have
[TABLE]
and hence R=R′∈G1(C′;R1,R2). This proves
G1(C;R1,R2)⊂G1(C′;R1,R2).
In the same way, we also have
G1(C;R1,R2)⊃G1(C′;R1,R2).
∎
5.3.2. Higher invariants Gn with n≥2
Now we construct more higher invariants Gn by induction.
Let n be an integer with n≥2, and assume that
[TABLE]
Then, we define
[TABLE]
In addition, for R∈Gn(C;{R1j,R2j}j=0n−1), we define
[TABLE]
Unlike the cases of G0 and G1,
the author doesn’t know whether
Gn(C;{R1j,R2j}j=0n−1) is empty or not,
while we see that it is finite.
(This is caused from the condition ∂z1=∂z2.)
However, if Gn(C;{R1j,R2j}j=0n−1) is non-empty,
then we can show that it is invariant under ν+-equivalence.
(As a consequence, the emptiness of Gn is also an invariant
of ν+-classes.)
Theorem 5.13**.**
Suppose that [C]ν+≤[C′]ν+ and the intersection
[TABLE]
has distinct two elements R1k and R2k
(where k=0,1,…,n−1, and {R1j,R2j}j=0−1=∅).
Then, for any R′∈Gn(C′;{R1j,R2j}j=0k−1), there exists an element
R∈Gn(C;{R1j,R2j}j=0k−1) with R⊂R′.
In particular, the non-emptiness of
Gn(C′;{R1j,R2j}j=0k−1) implies the non-emptiness of
Gn(C;{R1j,R2j}j=0k−1).
Proof.
The proof follows from arguments exactly the same as the proof of
Theorem 5.11. (We only need to care about the fact that
Rf(zi)∈Gn−1′(C;{R1j,R2j}j=0n−2),
but this also can be proved by induction.)
∎
Corollary 5.14**.**
For any [C]ν+∈Cf and
sequence of distinct two elements
R1k,R2k∈Gk(C;{R1j,R2j}j=0k−1)(k=0,1,…,n−1),
Gn(C;{R1j,R2j}j=0n−1)∈P(CR(Z2))
is an invariant of the ν+-class [C]ν+.
Proof.
The proof follows from arguments exactly the same as the proof of
Corollary 5.12.
(In fact, we only need to replace some symbols suitably.)
∎
5.4. Relationship to other invariants
In this subsection, we study the relationship of the new invariants
G0 and G1 to the invariants reviewed in Subsection 2.10.
5.4.1. Relationship of G0 to ν+, Vk, τ and Υ
We first discuss the relationship of G0 to ν+.
Here, recall R(k,l):={(i,j)∈Z2∣(i,j)≤(k,l)}.
Proposition 5.15**.**
For any formal knot complex C, the values ν+(C) and ν+(C∗) are determined from
G0(C) by the formulas
[TABLE]
and
[TABLE]
Proof.
We can see that the equality
[TABLE]
holds. Therefore, the first assertion immediately follows from Corollary 5.8.
Next, by Lemma 2.28, the inequality
ν+(C∗)>m holds if and only if there is a homological generator x∈C
with Rx⊂{i≤−1 or j≤−m−1}.
Here, we note that
Rx⊂{i≤−1 or j≤−m−1} if and only if
Rx⊃R(0,−m).
Therefore, we have
[TABLE]
Moreover, Lemma 5.4 implies
that any Rx∈G0′(C) includes R(0,−m)
if and only if any Rx∈G0(C) includes R(0,−m).
This completes the proof.
∎
From Proposition 5.15, we see that
G0 detects the zero element as a ν+-class.
Theorem 5.16**.**
For any formal knot complex C,
the following holds:
[TABLE]
Proof.
By the invariance of G0 under ∼ν+ and easy computation
G0(Λ)={R(0,0)}, the only-if-part obviously holds.
Moreover. the if-part immediately follows from Proposition 5.15,
since the unique element R:=R(0,0)∈G0(C) satisfies
R⊂R(0,0) and R⊃R(0,0).
∎
On the other hand, we will see in Subsection 5.5
that G0 is not a perfect invariant of ν+-classes.
We can also translate the invariants Vk, τ and Υ as follows:
[TABLE]
(Here, recall Rt(s):={(i,j)∈Z2∣(1−t/2)i+(t/2)j≤s}.)
Therefore, we have the following formulas.
Proposition 5.17**.**
For any formal knot complex C, the invariants Vk(C), τ(C) and
ΥC(t) are determined from
G0(C) by the formulas:
[TABLE]
5.4.2. Relationship of G1 to Υ2
Next, we discuss the relationship of G1 to Υ2.
(Precisely, we compare G1 with υ2 rather than Υ2.)
Let
[TABLE]
and then we see that the inequality
[TABLE]
holds for each sign. (Remark that it does not become the equality in general, since
we might have x∈gen0(C) such that
R⊊Rx⊂FυC(t±δ)t±δ
for some R∈G0t±(C). Such x is lying in
Z±(C) but not in the right-hand side.)
In particular, Zt−(C)∩Zt+(C)=∅
only if
G0t−(C)∩G0t+(C)=∅.
For any t∈(0,2), we set
[TABLE]
Then, we have the following inequality.
(In light of the inequality, we can regard υC,t2 as a linear approximation of G1t(C).)
Proposition 5.18**.**
For any formal knot complex C, t∈(0,2) and s∈[0,2],
the inequality
[TABLE]
holds.
Proof.
Denote the right-hand side of the inequality in Proposition 5.18
by υG1t(C)2(s).
Then, we can take R∈G1t(C) with
R⊂(Rt(υC(t))∪Rs(υG1t(C)2(s))).
Moreover, by the definition of G1t(C), there exists elements
R±∈G0t±(C) such that R−=R+
and R∈G1(C;R−,R+).
This implies that we have a homological generator
[TABLE]
for each sign
and 1-chain x∈CRx⊂CRt(υC(t))∪Rs(υG1t(C)2(s))
such that ∂x=z−−z+.
Here, by Lemma 2.10, we see
[TABLE]
and hence [z−]−[z+]=[∂x]=0∈H0(FυC(t)t+FυG1t(C)2(s)s).
This shows the desired inequality
υC,t2(s)≤υG1t(C)2(s).
∎
5.5. Genus one complexes with no realizing knot
In this subsection, we define the complexes Cn in Section 1 precisely,
and prove Theorem 1.8 and Corollary 1.9.
For any n∈Z>0, we define a F-vector space Cˉn
with a basis {xk,xk′,y}k=0n−1
and F-linear map ∂ˉ:Cˉn→Cˉn as follows:
•
gr(xk)=gr(xk′)=k and gr(y)=n (0≤k≤n−1).
•
∂ˉxk=∂ˉxk′=xk−1+xk−1′ and
∂ˉy=xn−1+xn−1′ (0≤k≤n−1),
where we define x−1+x−1′:=0.
•
(Alg(xk),Alex(xk))=(k,k+1), (Alg(xk′),Alex(xk′))=(k+1,k) and
(Alg(y),Alex(y))=(n,n) (0≤k≤n−1).
Then we can check that (Cˉ,∂ˉ) satisfies all conditions of
Lemma 2.3.
(Figure 1 in Section 1 depicts the complex (Cˉn,∂ˉ).)
Therefore, we have a formal knot complex
(C,∂) which is related to (Cˉ,∂ˉ)
as described in Lemma 2.3.
Note that C1 coincides with the knot complex for the right-hand trefoil T2,3.
Moreover, g(Cn)=1 for any n.
Proposition 5.19**.**
For any n∈Z>0, the formal knot complex Cn satisfies the following:
Moreover,
both R(0,1) and R(1,0) are minimal in {R(0,1),R(1,0)},
and hence we have
G0(Cn)={R(0,1),R(1,0)}.
Next, fix m∈{0,1,…,n−2},
and assume that the assertion (2)
holds for any 1≤k≤m. Then the equalities
[TABLE]
and
[TABLE]
must hold. Now we see
[TABLE]
and hence we can conclude
[TABLE]
This proves the assertion (2).
Similarly, we can prove the assertion (3).
∎
Now, we can easily prove the following theorems from the above computation.
Theorem 1.8**.**
The ν+-classes {[Cn]ν+}n=1∞ are mutually distinct in Cf,
while τ(Cn)=1 for any n. In particular, the complement F1f∖πν+(F1) is infinite.
Proof.
The first half assertion directly follows from Proposition 5.19.
Moreover, since the relations τ(k[T2,3]ν+)=k, τ(Cn)=1 and
[Cn]ν+=[C1]ν+=[T2,3]ν+ hold
for any k∈Z and n≥2,
we have [Cn]ν+=k[T2,3]ν+.
This proves the second half assertion.
∎
Corollary 1.9**.**
The formal knot complexes {Cn}n=2∞
cannot be realized by any knot in S3.
Proof.
If there exists a knot K with [CK]=[Cn] for some n≥2,
then it follows from Proposition 5.19 and Theorem 4.5
that τ(K)=τ(Cn)=1 and g(K)=1.
(Note that 1=g(Cn)≥min{g(C)∣C∈[Cn]=[CK]}=g(K)≥τ(K)=1.)
Therefore, by Theorem 1.2, we have
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