Abstract
In Maulik and Thomas (in preparation) the Vafa–Witten theory of complex projective surfaces is lifted to oriented \({\mathbb {C}}^*\)-equivariant cohomology theories. Here we study the K-theoretic refinement. It gives rational functions in \(t^{1/2}\) invariant under \(t^{1/2}\leftrightarrow t^{-1/2}\) which specialise to numerical Vafa–Witten invariants at \(t=1\). On the “instanton branch” the invariants give the virtual \(\chi ^{}_{-t}\)-genus refinement of Göttsche–Kool, extended to allow for strictly semistable sheaves. Applying modularity to their calculations gives predictions for the contribution of the “monopole branch”. We calculate some cases and find perfect agreement. We also do calculations on K3 surfaces, finding Jacobi forms refining the usual modular forms, proving a conjecture of Göttsche–Kool. We determine the K-theoretic virtual classes of degeneracy loci using Eagon–Northcott complexes, and show they calculate refined Vafa–Witten invariants. Using this Laarakker (Monopole contributions to refined Vafa–Witten invariants. arXiv:1810.00385) proves universality results for the invariants.
Similar content being viewed by others
Avoid common mistakes on your manuscript.
1 Introduction
Numerical. Vafa–Witten invariants should exist for all Riemannian 4-manifolds S [VW], but mathematicians have yet to find a general definition. When \((S,{\mathcal {O}}_S(1)\) is a smooth complex projective surface the invariants were defined in [TT1, TT2]. However, physicists are by now less interested in numerical Vafa–Witten invariants, which they mostly know how to calculateFootnote 1 in rank 2. They care more about the refined Vafa–Witten invariants which arise in topologically twisted maximally supersymmetric 5d super Yang-Mills theory, but which do not have a mathematical definition.
Joyce/Kontsevich-Soibelman. So we would like to refine the numerical invariants [TT1, TT2] on a smooth complex polarised surface \((S,{\mathcal {O}}_S(1))\). Those numerical invariants are closely related to local DT invariants of the local Calabi-Yau threefold \(X=K_S\). (In fact when \(H^1({\mathcal {O}}_S)=H^2({\mathcal {O}}_S)\) they are precisely local DT invariants, as studied in [GSY1, GSY2] for instance.) They count certain compactly supported 2-dimensional torsion sheaves on X via localisation with respect to the obvious \(T={\mathbb {C}}^*\) action on X.
If they were defined by Euler characteristic localisation—weighted by the Behrend function [Be]—they would have an obvious refinement given by the work of Team Joyce and Kontsevich-Soibelman. But Euler characteristic localisation gives the wrong answer, and in fact the invariants of [TT1, TT2] are defined by virtual localisation.
Nekrasov-Okounkov. For threefolds X with a \({\mathbb {C}}^*\) action, Nekrasov and Okounkov [NO] give a different refinement of DT theory via equivariant virtual K-theoretic invariants. This means replacing the length of the 0-dimensional virtual cycle (the classical DT invariant) by the holomorphic Euler characteristic of the virtual structure sheaf. This gives the same numerical answer, but also allows for a refinement by using the T action to promote dimensions of cohomology groups to characters of T. The result is rational functions of t which specialise at \(t=1\) to the old numerical invariants.
In fact Nekrasov-Okounkov twist by a square root of the virtual canonical bundle of the moduli space before taking (equivariant) holomorphic Euler characteristic. This is motivated by physics, relating the \({\overline{\partial }}\) operator to the Dirac operator. From an algebro-geometric point of view, it makes the refinement more symmetric: it is a rational function in \(t^{1/2}\) which, by Serre duality, is invariant under \(t^{1/2}\leftrightarrow t^{-1/2}\). The choice of square root is equivalent to the choice of orientation data in the Joyce/Kontsevich-Soibelman theory. Fortunately in our setting there is a canonical choice on the T-fixed locus: see Proposition 2.6 below.
Vafa–Witten refinement. Under certain circumstances Davesh Maulik [Ma] proved that the K-theoretic and Joyce/Kontsevich-Soibelman refinement of DT theory coincide. (The most general refinement is based on the two variable Hodge–Deligne polynomial; here we are concerned with the Hirzebruch \(\chi ^{}_{-t}\) one variable specialisation.) So he suggested that it is natural to try to also refine Vafa–Witten theory using T-equivariant K-theory. That is what we do in this paper. We use the Vafa–Witten perfect obstruction theory of [TT1, TT2] to produce a virtual structure sheaf, and then twist by the square root (2.7) of the virtual canonical bundle. We then use a virtual localisation formula to take equivariant holomorphic Euler characteristic. In Theorem 5.15 we reprove Maulik’s result that this refinement recovers the refined DT invariant when \(\deg K_S<0\).
Further refinements. In fact this is a special case of more general refinements. Recall [BF] that virtual cycles come from intersecting a cone in a vector bundle \(C\subset E\) over moduli space M with the zero section \(\iota :0_E\hookrightarrow E\) of the vector bundle. One can intersect these two cycles [C] and \([0_E]\) in any oriented cohomology theory. Traditionally we use Fulton-MacPherson intersection theory to get the virtual cycle in homology [BF],
In K-theory we instead take the (derived) tensor product of the structure sheaves of the two cycles [FG, CFK],
The result is slightly different—differing by a Todd class, by virtual Riemann–Roch—and therefore interesting! (Especially when we work equivariantly with respect to the T action.)
To get the Nekrasov-Okounkov-twisted version of this used in our paper we instead take the intersection in \({ KO}\)-theory. This replaces the K-theoretic “fundamental classes" \({\mathcal {O}}_Z\) of submanifolds by their twists by \(K_Z^{1/2}\) (this is the Atiyah–Bott–Shapiro complex orientation, and is well defined over \({\mathbb {Z}}\) only for spin manifolds).
The universal case is complex cobordism theory; see [Sh, GK2] for instance. From this one can pass to all other oriented cohomology theories, such as “topological modular forms”.Footnote 2 In Vafa–Witten theory, the three T-equivariant cohomology theories
give rise to virtual versions of
of the Vafa–Witten moduli space M respectively. On the “instanton locus" these produce the
of the moduli space of instantons (or Gieseker stable sheaves) on the surface S. (This apparent paradox is because the Vafa–Witten obstruction theory on the instanton moduli space differs from its usual obstruction theory.)
Calculations give generating series which seem to be
respectively; in particular see [GK2] for the instanton locus contributions in rank 2.
These refinements of Vafa–Witten theory are defined and studied in the forthcoming paper [MT2]. In this paper we specialise the general definition from [MT2] to T-equivariant K-theory and explore it in more detail.
Results. In Sect. 2 we give a careful treatment of virtual K-theoretic localisation for T-equivariant K-theory on quasi-projective T-schemes with a T-equivariant perfect obstruction theory and compact T-fixed locus. This allows us to define K-theoretic invariants for such schemes endowed with a choice of square root of the virtual canonical bundle. For simplicity, in this Introduction we state our results for symmetric perfect obstruction theories; then Proposition 2.6 gives a canonical choice (2.7) of this square root.
Theorem
Let M be a quasi-projective T-scheme with compact T-fixed locus, and a T-equivariant symmetric perfect obstruction theory. Then the refined invariant
of Definition 2.19 is a rational function of \(t^{\frac{1}{2}}\), invariant under \(t^{\frac{1}{2}}\leftrightarrow t^{-\frac{1}{2}}\). It is deformation invariant and has poles only at roots of unity and the origin, but not at \(t=1\). Specialising to \(t=1\) recovers the numerical invariant defined by T-equivariant localisation,
Stable case. In Sect. 4 we apply this to the Vafa–Witten moduli space for a projective surface S and a charge \(\alpha \in H^*(S)\) for which semistability implies stability.Footnote 3 The moduli space carries a symmetric perfect obstruction theory and a T action inherited from the T action on X. The result is invariants which specialise to the numerical Vafa–Witten invariants [TT1]
This \(\mathsf {VW}_\alpha (t)\) is made up of contributions from the two types of component of the T-fixed locus:
-
the “instanton branch” of sheaves on S pushed forward to X,
-
the “monopole branch” of T-equivariant sheaves supported on a nontrivial scheme theoretic thickening of \(S\subset X\).
Semistable case. We tackle the general case in Sect. 5. We use Joyce–Song pairs to rigidify semistable sheaves as in [TT2]. The resulting refined pair invariants \(P^\perp _{\alpha ,n}(t)\) are functions of the twisting parameter \(n\gg 0\) of the Joyce–Song pairs. According to Conjecture 5.2 they should be expressable in terms of certain universal functions in n,
if \(H^{0,1}(S)=0=H^{0,2}(S)\); otherwise we take only the first term in the sum:
The coefficients \(\mathsf {VW}_\alpha (t)\) then define the refined Vafa–Witten invariants. Here \([\chi ]^{}_t\) is the quantum integer
Since \([\chi ]^{}_t\rightarrow \chi \) as \(t\rightarrow 1\), Conjecture 5.2 specialises to Conjecture 6.5 of [TT2], now proved in many cases [TT2, MT1]. Here we prove the refined conjecture in some situations.
Theorem
Conjecture 5.2 holds, thus defining refined Vafa–Witten invariants \(\mathsf {VW}_\alpha (t)\), in the following cases.
-
When all semistable sheaves of charge \(\alpha \) are stable. In this case \(\mathsf {VW}_\alpha (t)\) recovers the invariants (1.1).
-
\({\mathbf {K}}_{\mathbf {S}}<{\mathbf {0}}\). When \(\deg K_S<0\), for any charge \(\alpha \). Here we recover refined Footnote 4 DT invariants: \(\mathsf {VW}_\alpha (t)={\mathsf {J}}_\alpha (t)\).
-
\({\mathbf {K}}_{\mathbf {S}}={\mathbf {0}}\). When S is a K3 surface and the charge \(\alpha \) is primitive or a prime multiple of a primitive class.
-
\({\mathbf {K}}_{\mathbf {S}}>{\mathbf {0}}\). When \(p_g(S)>0\), for any charge \(\alpha \) with prime rank, Laarakker [La2] shows that the conjecture holds for the contribution of the monopole locus. He uses the vanishing Theorem 5.23 to remove many components, and [GT1, GT2] to calculate with the rest.
K3 surfaces. We are able to do extensive calculations when S is a K3 surface. The well-known \(1/d^2\) multiple cover formula of DT theory is replaced by a \(1/[d]_t^2\) multiple cover formula (5.39) in the refined setting. (This is a surprising contrast to the \(1/d[d]_t\) refined multiple cover formula seen in DT theory—see [DM, Section 6.7] for instance.) At the level of generating series we are led to the conjecture
where \({\widetilde{\Delta }}\) is the Jacobi form
When the rank r is prime this reduces to a conjecture of Göttsche–Kool [GK3] which we prove in Theorem 5.48.
Theorem
Let S be a K3 surface with generic polarisation \({\mathcal {O}}_S(1)\). Then (1.3) holds for prime r.
Modularity. On the instanton branch \({\mathcal {M}}\) our refined Vafa–Witten invariants recover the virtual \(\chi ^{}_{-t}\)-genus refinement studied by Göttsche–Kool on surfaces with \(K_S>0\) [GK1]. This is most easily seen when \({\mathcal {M}}\) is smooth and unobstructed as a moduli space of fixed-determinant sheaves on S. Then its Vafa–Witten obstruction bundle is \(\Omega _{{\mathcal {M}}}\otimes {\mathfrak {t}}\) so that
Therefore
so that \(\chi ^{}_t({\widehat{{\mathcal {O}}}}^{\,{\text {vir}}}_{\!{\mathcal {M}}})=(-1)^{\dim {\mathcal {M}}}\,{\mathfrak {t}}^{-\dim {\mathcal {M}}/2}\chi ^{}_{-t}({\mathcal {M}})\).
Applying modularity to Göttsche–Kool’s calculations of these invariants gives predictions for the contribution of the “monopole branch". We calculate a small number of cases (which nonetheless take 9 pages of calculation) and find perfect, honestFootnote 5 agreement.
Nested Hilbert schemes. There are components of the monopole branch which are nested Hilbert schemes of S. In [GT1, GT2] it was shown how to view these as degeneracy loci in smooth products of Hilbert schemes of S. This induces a virtual cycle which agrees with the one from Vafa–Witten theory. Its pushforward is described by the Thom–Porteous formula. This gives a more systematic way to compute numerical Vafa–Witten invariants as integrals over products of smooth Hilbert schemes.
In Sect. 3 we describe K-theoretic analogues of these results, replacing Chern classes by Koszul resolutions and the Thom–Porteous formula by Eagon–Northcott complexes. The most straightforward result, relevant to nested Hilbert schemes of points on a surface, is the following.
Theorem
Given a map of vector bundles \(\sigma :E_0\rightarrow E_1\) over a smooth scheme X, the locus Z where \(\sigma \) is not injective carries a natural virtual structure sheaf whose pushforward to X has K-theory class
where \(r={\text {rank}}E_1-{\text {rank}}E_0\).
When the degeneracy locus Z has the correct codimension, the Eagon–Northcott complex of \(\sigma :E_0\rightarrow E_1\)—whose K-theory class is the right hand side of (1.4)—is well known to resolve \(\iota _*\,{\mathcal {O}}_Z\). So the above result shows that even when it has the wrong codimension, its K-class is \(\iota _*\,{\mathcal {O}}^{{\text {vir}}}_Z\in K_0(X)\).
Carlsson–Okounkov [CO] express the Thom–Porteous class of [GT1] in terms of Grojnowski–Nakajima operators. There are K-theoretic analogues of this in [CNO, MO, SV] to which we intend to return.
We also relate \({\mathcal {O}}_Z^{{\text {vir}}}\) to the Vafa–Witten virtual structure sheaf when Z is a nested Hilbert scheme. The upshot is that monopole branch contributions to refined Vafa–Witten invariants can be computed from calculations on smooth products of Hilbert schemes of S.
Laarakker. In [La1] (stable case) and [La2] (general case) Laarakker uses this to great effect on surfaces with \(p_g>0\) (and \(h^{0,1}=0\) for now). Things work best in prime rank, using the vanishing Theorem 5.23 to eliminate many components of the monopole locus. The rest can be calculated via universal integrals over Hilbert schemes of points and curves on surfaces using the results of [GT1, GT2].
Moreover, the contributions from points and curves split, in an appropriate sense. The curves contribute Seiberg-Witten invariants (certain well-understood integrals over linear systems). Laarakker evaluates the contributions of Hilbert schemes of points via the method of [EGL]. The result depends only on the curve class \(\beta \in H_2(S,{\mathbb {Z}})\) and the cobordism class of the surface—and thus only on \(c_1(S)^2,\,c_2(S)\) and \(\beta ^2\). Therefore these contributions can be calculated on K3 surfaces and toric surfaces (despite these not having \(p_g>0\)!).
Theorem
[La1] Let S be a minimal general type surface with \(p_g(S)>0\) and \(H_1(S,{\mathbb {Z}})=0\) such that \(K_S\) does not admit a square root. We work with rank 2 Higgs pairs \((E,\phi )\) with \(\det E=K_S\). Then the monopole branch contributions to the refined Vafa–Witten generating series \(\sum _n\mathsf {VW}_{2,K_S,n}(t)\,q^n\) can be written
where
are universal functions, independent of S.
Furthermore K3 calculations determine A(t, q) completely, while by modularity and the work of Göttsche–Kool he knows what B(t, q) should be, and he can check this in low degree by toric computations.
2 K-Theoretic Virtual Cycles
The foundations of cohomological virtual cycles are laid down in [BF, LT]; we use the notation from [BF]. The foundations for K-theoretic virtual cycles (or “virtual structure sheaves") are laid down in [CFK, FG]; we use the notation from [FG].
2.1 Virtual cycle and virtual structure sheaf
Let M be a quasi-projective scheme with a perfect obstruction theory \(E^{\bullet }\rightarrow {\mathbb {L}}_M\) supported in degrees \([-1,0]\). That is, \(E^{\bullet }\) is a 2-term complex \(E^{-1}\rightarrow E^0\) of vector bundles on M such that the map \(E^{\bullet }\rightarrow {\mathbb {L}}_M\) induces an isomorphism on \(h^0\) and a surjection on \(h^{-1}\). We call \({\mathbb {L}}_M^{{\text {vir}}}:=E^{\bullet }\) the virtual cotangent bundle of M, of rank \({\text {vd}}:={\text {rank}}E^0-{\text {rank}}E^{-1}\) and determinant
Dualising, we set \(E_i:=(E^{-i})^*\) to get the virtual tangent bundle
By [BF] this data defines a cone \(C\subset E_1\) from which we may define M’s virtual cycle
and its virtual structure sheaf [FG]
where \(\iota ^{}_0:M\rightarrow E_1\) is the zero section. (Since \(\iota ^{}_0\) is a regular embedding, \(L\iota _0^*\,{\mathcal {O}}_C\) is a bounded complex.) If M is compact the virtual Riemann–Roch theorem of [FG, Corollary 3.4] then gives
In particular, if M also has virtual dimension zero \({\text {vd}}=0\) we can use either the virtual structure sheaf or the virtual cycle to define the same numerical invariant
2.2 Twisted virtual structure sheaf
Via the medium of Nekrasov and Okounkov, physics teaches us that we should choose a square root of the virtual canonical bundle and work instead with the twisted/modified/symmetrisedFootnote 6 virtual structure sheaf,
This paper is mainly concerned with the virtual K-theoretic invariant \(\chi ({\widehat{{\mathcal {O}}}}^{\,{\text {vir}}}_{\!M})\). When M is compact the virtual Riemann–Roch theorem [FG, Corollary 3.4] gives the following cohomological expression for it,
modifying (2.2). Of course in virtual dimension zero this makes no difference and we recover (2.3),
but it will make a big difference to its refinement when we work equivariantly. This will also allow us to fix the ambiguity in the choice of \(K_{{\text {vir}}}^{1/2}\), because on the fixed locus there is a canonical choice.
Proposition 2.6
Let M be a quasi-projective scheme with a \(T={\mathbb {C}}^*\) action with projective fixed locus \(M^T\). Suppose M has a T-equivariant symmetric perfect obstruction theory \(E^{\bullet }\rightarrow {\mathbb {L}}_M\). Then \(K_{M,{\text {vir}}}\big |_{M^T}\) admits a canonical square rootFootnote 7
Here \(\big (E^{\bullet }|^{}_{M^T}\big )^{\ge 0}\) denotes the part of \(E^{\bullet }|_{M^T}\) with nonnegative T-weights, and \(r^{}_{\ge 0}\) is its rank.
Proof
Decompose the virtual cotangent bundle in weight spaces for the T action,
Here each \(F^i\) is a T-fixed two-term complex of vector bundles on \(M^T\) of (super)rank \(r_i:={\text {rank}}(F^i)\). The symmetry of the obstruction theory,
implies that
Therefore
\(\square \)
2.3 Localisation
Suppose as above \(T:={\mathbb {C}}^*\) acts on both M and its perfect obstruction theory \(E^{\bullet }\rightarrow {\mathbb {L}}_M\). Then on its fixed locus \(\iota :M^T\hookrightarrow M\) we get a splitting
into fixed and moving parts (i.e. weights 0 and nonzero). By [GP] the fixed part \((E^{\bullet })^T\) defines a perfect obstruction theory on \(M^T\) (and so a virtual structure sheaf (2.1)). We call the dual of the moving summand the virtual normal bundle \(N^{{\text {vir}}}\). The virtual localisation formula of [GP] states that
Here we consider the T-equivariant Chow homology to be a module over \(H^*(BT)={\mathbb {Z}}[t]\), which we localise, inverting the equivariant parameter t—the first Chern class of the weight 1 irreducible representation \({\mathfrak {t}}\) of T. This ensures that, writing \(N^{{\text {vir}}}\) as a two-term complex of T-equivariant vector bundles \(N_0\rightarrow N_1\)all of whose weights are nonzero, the \(c_{\mathrm {top}}(N_i)\) are invertible. Thus we may define \(e(N^{{\text {vir}}}):=c_{\mathrm {top}}(N_0)/c_{\mathrm {top}}(N_1)\).
To mimic this in K-theory we use the module structure of \(K^0_T(M)\) over \(K^0_T(\mathrm {point})={\mathbb {Z}}[t,t^{-1}]\) to localise to the field of fractionsFootnote 8\({\mathbb {Q}}(t)\). Adjoining \(t^{1/2}\) (so we can lift our choice of square root (2.7) to localised T-equivariant K-theory), we work in
Now applying (2.8) to (2.5), and using the notation \(\Lambda ^{\bullet }E:=\sum _{i\ge 0}(-1)^i\Lambda ^iE\) in K-theory, we find
the last line from the virtual Riemann–Roch theorem [FG, Corollary 3.4] on \(M^T\). This suggests there should be a K-theoretic localisation formula
from which (2.9) would follow by taking \(\chi \big (\ \cdot \ \otimes K^{\frac{1}{2}}_{{\text {vir}}}\big )\).
Such a result is proved in [CFK, Theorem 5.3.1] for \((M,E^{\bullet })\) which can be enhanced to a [0, 1]-dg-manifold structure. More recently Qu has proved (2.10) for any T-equivariant \((M,E^{\bullet })\) [Qu].
For the first version of this paper I was unaware of Qu’s work, and did not want to have to prove that Vafa–Witten moduli spaces M admit a T-equivariant [0, 1]-dg-manifold structure (though they certainly do). So I proved a weaker statement—a T-equivariant version of (2.9), which is sufficient for our purposes. I have kept that proof—which is Proposition 2.13 below—since it demonstrates the compatiblity of K-theoretic and cohomological localisation under virtual Riemann–Roch. So we turn to this now.
2.4 Refinement
We are interested in situations where M may be noncompact, but carries a T action with compact fixed locus \(M^T\). Then (2.2) and (2.5) make no obvious sense, but their natural refinements—given by replacing (super)ranks of graded vector spaces by characters of (virtual) T-modules—are perfectly well-defined. That is, we define
Here the left hand side may involve infinite direct sums; then the right hand side will be a sum of power series in \(t^{1/2}\) and \(t^{-1/2}\) which, in our situation, will be expansions of rational functions in \({\mathbb {Q}}(t^{1/2})\). When the sums are finite we may set \(t=1\) and recover the usual Euler characteristic or (super)rank.
Applying (2.11) to \(R\Gamma \big (M,{\widehat{{\mathcal {O}}}}^{\,{\text {vir}}}_{\!M}\big )\) gives our refinement of the integer (2.5).
When M is compact this specialises to (2.5) at \(t=1\), but (2.12) makes sense more generally.
Proposition 2.13
Suppose \(M^T\) is compact and we have chosen a square root \(K^{1/2}_{{\text {vir}}}\in K^T_0(M)(t^{1/2})\). Then the refined invariant (2.12) can be calculated on \(M^T\) by localisation as
Proof
This follows directly from the localisation formula (2.10) of [CFK] when M is a [0, 1]-dg-manifold acted on by T, and from [Qu] more generally. Alternatively, we can repeat the argument of (2.9) in an equivariant setting, replacing the virtual Riemann–Roch formula of [FG, Corollary 3.4] by its equivariant analogue.
We use the standard trick of approximating the homotopy quotient \(M\times _T ET\) over \(BT={\mathbb {P}}^\infty \) by the M-bundle
(Here T acts with weight 1 on \({\mathbb {C}}^{N+1}\).) Applying the virtual Grothendieck–Riemann–Roch theorem of [FG, Theorem 3.3] to \(p^{}_N\) gives
As N increases this is a sequence of compatible cohomology classes over \({\mathbb {P}}^N\subset {\mathbb {P}}^{N+1}\subset \cdots \), defining a class in
By (2.8) its class in \(H^*_T(M,{\mathbb {R}})\otimes _{{\mathbb {R}}[t]}{\mathbb {R}}(\!(t)\!)\) is equal to
Again, we spell out what this means in terms of the finite dimensional models. We can expand \(1/e(N^{{\text {vir}}})\) as an \(H^*(M)\)-valued Laurent series in \(t^{-1}\). Write it as a sum of terms \(a_it^i\), where \(a_i\in H^{-2{\text {rank}}(N^{{\text {vir}}})-2i}(M)\). This therefore vanishes for \(-{\text {rank}}(N^{{\text {vir}}})-i>\dim M\), i.e. for i sufficiently negative. Therefore \(1/e(N^{{\text {vir}}})\) is a Laurent polynomial in t, and we may pick \(n\gg 0\) such that \(t^n\cdot 1/e(N^{{\text {vir}}})\in H^*_T(M,{\mathbb {R}})\otimes _{{\mathbb {R}}[t]}{\mathbb {R}}[\![t]\!]\subset H^*_T(M,{\mathbb {R}})\otimes _{{\mathbb {R}}[t]}{\mathbb {R}}(\!(t)\!)\). Then the statement is that \(\varprojlim \)(2.15) is \(t^{-n}\) times by the inverse limit of the compatible sequence of cohomology classes
Using \(e(N^{{\text {vir}}})={\text {ch}}(\Lambda ^{\bullet }(N^{{\text {vir}}})^\vee ){\text {Td}}(N^{{\text {vir}}})\) and \(T^{{\text {vir}}}_M\big |_{M^T}=T^{{\text {vir}}}_{M^T}+N^{{\text {vir}}}\) in K-theory, these classes are
Let \(q^{}_N:M^T\times _T({\mathbb {C}}^{N+1}\backslash \{0\})=M^T\times {\mathbb {P}}^N\rightarrow {\mathbb {P}}^N\) denote the restriction of \(p^{}_N\). Applying [FG, Theorem 3.3] to \(q^{}_N\) gives
Since the Chern character of any (virtual) T-representation V is \({\text {ch}}(V)=\chi ^{}_{e^t}(V)\), the upshot is
Substituting \(s=e^t\) gives the result. \(\quad \square \)
Now we have localised to \(M^T\) we can use the canonical square root (2.7) of Proposition 2.6 to make an unambiguous definition of our refined invariants.
Assumption 2.18
We will assume
-
(1)
M is a quasi-projective T-variety with projective fixed locus \(M^T\),
-
(2)
M has a T-equivariant symmetric obstruction theory.
By Proposition 2.6, this implies the existence of
-
a T-equivariant perfect obstruction theory with \({\text {vd}}=0\), and
-
a choice of line bundle on \(M^T\) whose square is \(K_{M,{\text {vir}}}|_{M^T}\),
and this is all we will actually use. So although it is more elegant to assume (1) and (2) from now on, the reader can replace (2) by the above two conditions instead to get a slightly more general result. We then call the line bundle \(K^{1/2}_{M,{\text {vir}}}\big |_{M^T}\).
Definition 2.19
Suppose M satisfies (2.18). Then we define its refined K-theoretic invariant \(\chi ^{}_t\big (M,{\widehat{{\mathcal {O}}}}^{\,{\text {vir}}}_{\!M}\big )\) to be
where \(K^{\frac{1}{2}}_{M,{\text {vir}}}\big |_{M^T}\) is the canonical choice (2.7).
Again, when M is compact, (2.20) specialises to (2.5) at \(t=1\). When M is noncompact (but \(M^T\) is compact) and has virtual dimension \({\text {vd}}=0\) we can still define a cohomological substitute for (2.5) or (2.2) (both of which are \(\int _{[M]^{{\text {vir}}}}1\) in the compact case) by localisation (2.8) as follows:
This lies in \({\mathbb {Q}}\subset {\mathbb {Q}}[t,t^{-1}]\) because \({\text {vd}}(M)=0\) implies that \({\text {rank}}N^{{\text {vir}}}=-{\text {vd}}(M^T)\). Then (2.20) refines (2.21) even when M is noncompact:
Proposition 2.22
If M satisfies (2.18) then (2.20) is a rational function of \(t^{1/2}\) with poles only at roots of unity and the origin, but not at 1. We may therefore specialise to \(t=1\), where we recover the rational number (2.21):
Proof
We compute
We wish to evaluate this at \(t=0\) (i.e. \(e^t=1\)). Writing \(K^{\frac{1}{2}}_{{\text {vir}}}=L{\mathfrak {t}}^w\) for some \(w\in {\mathbb {Z}}[1/2]\), we expand
where \(c_i\in H^{2i}(M^T)\) and \(c,d_i,e_i\in H^{>0}(M^T)\). Therefore \(c_i=0\) for \(i\gg 0\) and the first series is a finite sum. Consider multiplying it by the last series.
-
The \(t^{<0}\) terms of the first series all have coefficients in \(H^{>2{\text {vd}}(M^T)}(M^T)\) (both before and after multiplication by the last series). These integrate to zero against \([M^T]^{{\text {vir}}}\).
-
The \(t^{>0}\) terms of the first series go to 0 at \(t=0\), and the same is true when they are multiplied by the last series.
So we are left with the \(c_{{\text {vd}}(M^T)}t^0\) term of the first series. When multiplied by any \(e_i\) we get a class in \(H^{>2{\text {vd}}(M^T)}(M^T)\) whose integral over \([M^T]^{{\text {vir}}}\) is zero. So when we multiply \(c_{{\text {vd}}(M^T)}t^0\) by the last series and integrate, we get the same as just (multiplying by 1 and) integrating; this contributes
This gives the numerical result claimed. But since it doesn’t give the statement about rationality, we now go back to the first line of (2.23) and expand everything in sight carefully.
Write \((N^{{\text {vir}}})^\vee =N^0-N^1\) as a global difference of two T-bundles with nonzero weights. Let the Chern roots of \(N^0\) and \(N^1\) be \(x_i+w_it\) and \(y_j+v_jt\) respectively, where \(w_i,v_j\) are all nonzero integers. Letting \(s:=e^t\), we have
where \(E(u):=e^u-1\) is the power series \(u+u^2/2!+u^3/3!+\cdots \).
If we write \(1-q^v=(1-q)[v]'_q\), where \([v]'_q:=1+q+q^2+\cdots +q^{v-1}\) is the quantum integer,Footnote 9 this becomes
Now \(E(x_i)=x_i+x_i^2/2+x_i^3/3!+\cdots \) lies in cohomological degrees \(\ge 2\), so, when we multiply out, any \((1-s)^{-j}\) term comes multiplied by a term \(a_js^{u_j}\), where \(a_j\) has cohomological degree \(\ge 2j\) on \(M^T\) (and \(u_j\) is an integer). And \(-{\text {rank}}(N^{{\text {vir}}})={\text {vd}}(M^T)\), so on restriction to \([M^T]^{{\text {vir}}}\) we get
by ignoring all cohomology classes which have degree \(\ge 2\dim [M^T]^{{\text {vir}}}=2{\text {vd}}(M^T)\).
Since \(T^{{\text {vir}}}_{M^T}\) is a fixed complex with trivial T action, \({\text {ch}}(K_{{\text {vir}}}^{1/2}){\text {Td}}(T^{{\text {vir}}}_{M^T})=s^w(1+\sigma )\) for some \(\sigma \in H^{\ge 2}(M^T)\) with no t (or s) dependence. Multiplying by (2.25) and integrating, (2.23) becomes
Thus \(\chi ^{}_s\) is a rational function of \(s^{1/2}\) with poles only at roots of unity and possibly zero, but not 1, as required.
Since we’ve got this far we may as well use (2.26) to give another derivation of the evaluation at \(s=1\). This gives
This integral sees only the part of \(a_{{\text {vd}}}\) which has degree precisely \(2\!\,{\text {vd}}\), so only the degree 2 parts \(x_i,\,y_j\) of \(E(x_i),\,E(y_j)\) in (2.24) contribute to it. So replacing \(E(x_i),\,E(y_j)\) by \(x_i,\,y_j\) in (2.24), it becomes the cohomological degree \({\text {vd}}\) part of
To evaluate at \(s=1\), we now reuse t to denote \(s-1\) and take the coefficient of \(t^0\) in the Laurent expansion (in \(t^{-1}\)!) of
When we expand \(1/e(N^{{\text {vir}}})\) as a Laurent series in \(t^{-1}\) the coefficient of \(t^i\) lies in \(H^{2{\text {vd}}(M^T)-2i}(M^T)\). Therefore integrating over \([M^T]^{{\text {vir}}}\) takes only the \(t^0\) term. We conclude again that
\(\square \)
Proposition 2.27
The refinement (2.20) is a rational function of \(t^{\frac{1}{2}}\) (with poles only at roots of unity and the origin) invariant under \(t^{\frac{1}{2}}\leftrightarrow t^{-\frac{1}{2}}\), and is deformation invariant.
Proof
All that is left to prove is the invariance under \(t^{\frac{1}{2}}\leftrightarrow t^{-\frac{1}{2}}\). This follows from the “weak virtual Serre duality" of [FG, Proposition 3.13] on \(M^T\):
where the last equality is from the identity
\(\square \)
2.5 Shifted cotangent bundles
When M is the \((-1)\)-shifted cotangent bundle \(T^*[-1]M^T\) of a quasi-smooth derived projective scheme \(M^T\), with the obvious \(T={\mathbb {C}}^*\) action on the fibres, it has a symmetric perfect obstruction theory and the refined invariant (2.20) simplifies. Letting p denote the projection \(M\rightarrow M^T\) we get the exact triangle
where \({\mathfrak {t}}\) denotes the standard weight 1 representation of T. In particular \(K_{M,{\text {vir}}}\ =\ p^*(K_{M^T,{\text {vir}}})^2\otimes {\mathfrak {t}}^{{\text {vd}}(M^T)}\) and the canonical choice (2.7) of square root is just
On the zero section \(M^T\subset M\) the exact triangle (2.29) gives
Therefore, using both (2.30) and the identity (2.28), we have in localised K-theory,
Substituted into (2.20), this gives the following result.
Proposition 2.31
If \(M^T\) is a quasi-smooth derived projective scheme, the K-theoretic refined invariant (2.20) of \(M=T^*[-1]M^T\) is
where \(\chi ^{{\text {vir}}}_y\) is the virtual \(\chi ^{}_y\)-genus of Fantechi–Göttsche [FG]. Specialising to \(t=1\) gives the signed virtual Euler characteristic studied in [JT].\(\quad \square \)
3 K-Theoretic Invariants from Degeneration Loci
Fix a map of bundles
of ranks \(r_0,r_1\) over a smooth ambient space X. We suppose for simplicityFootnote 10 that \(\dim \ker (\sigma |_x)\le 1\) for all points \(x\in X\). Then we let
denote the degeneracy locus of \(\sigma \). Its scheme structure is defined by the vanishing ideal of \(\Lambda ^{r_0}\sigma \)—the ideal generated by the \(r_0\times r_0\) minors of \(\sigma \).
Furthermore it is shown in [GT1] that \(D(\sigma )\) inherits a perfect obstruction theory by seeing it as the vanishing locus of the composition
This perfect obstruction theory depends only on the complex \(E_0\rightarrow E_1\) up to quasi-isomorphism, and endows \(D(\sigma )\) with a virtual cycle of codimension \(r_1-r_0+1\) whose pushforward to X is described in [GT1] by the Thom–Porteous formula as
3.1 K-theoretic degeneracy loci
The above perfect obstruction theory induces a virtual structure sheaf \({\mathcal {O}}^{{\text {vir}}}_{D(\sigma )}\) on the degeneracy locus by (2.1).
The K-theoretic analogue of the Thom–Porteous formula is the Eagon–Northcott complex of \(\sigma \). When \(D(\sigma )\) has the correct codimension, this complex is well known to resolve \({\mathcal {O}}_{D(\sigma )}\). Here we show that even when it has the wrong codimension, the K-theory class of the Eagon–Northcott complex is \({\mathcal {O}}^{{\text {vir}}}_{D(\sigma )}\in K_0(X)\).
Theorem 3.3
The pushforward of \({\mathcal {O}}^{{\text {vir}}}_{D(\sigma )}\) to X has K-theory class
where \(r={\text {rank}}E_1-{\text {rank}}E_0\).
Proof
The composition (3.1) defines a section \({\widetilde{\sigma }}\in \Gamma (q^*E_1(1))\) which cuts out \(D(\sigma )\subset {\mathbb {P}}(E_0)\). This defines the virtual structure sheaf
where \(\iota ^{}_0:D(\sigma )\hookrightarrow q^*E_1(1)\big |_{D(\sigma )}\) is the zero section and
is the cone over \(D(\sigma )\) defined by \({\widetilde{\sigma }}\). This is the flat limit, as \(t\rightarrow \infty \), of the graphs \(\Gamma _{t{\widetilde{\sigma }}}\subset q^*E_1(1)\). Therefore, in K-theory,
where \(j:D(\sigma )\hookrightarrow {\mathbb {P}}(E_0)\) and \(\iota :{\mathbb {P}}(E_0)\hookrightarrow q^*E_1(1)\) is the zero section.
Suppressing some obvious pullback maps for clarity, \(\Gamma _{{\widetilde{\sigma }}}\) is cut out of the total space of \(q^*E_1(1)\) by the section \({\widetilde{\sigma }}-\sigma _{\mathrm {taut}}\) of the pullback of \(q^*E_1(1)\). This induces a Koszul resolution of \({\mathcal {O}}_{\Gamma _{{\widetilde{\sigma }}}}\) on the total space of \(q^*E_1(1)\). Applying \(L\iota ^*\) restricts this to the zero section, where \(\sigma _{\mathrm {taut}}\) is zero. Thus the right hand side of (3.4) is the Koszul complex \(\big (\Lambda ^{\bullet }(q^*E_1(1))^*,{\widetilde{\sigma }}\big )\) (which is not in general exact, since \(\Gamma _{{\widetilde{\sigma }}}\) does not generally intersect the zero section transversally). Thus
where \(r_i:={\text {rank}}(E_i)\).
Finally we push down to X, using (by Serre duality)
Thus, applying \(Rq_*\) to (3.5), we find the pushforward of \({\mathcal {O}}_{D(\sigma )}^{{\text {vir}}}\) to K(X) is
where \(r=r^{}_1-r^{}_0={\text {rank}}(E_1-E_0)\). \(\quad \square \)
There are different formulae for (more general) K-theoretic degeneracy loci in [HIMN, A], essentially given by the Thom–Porteous formula with cohomological Chern classes replaced by K-theoretic Chern classes. By some algebraic identities these formulae are surely equivalent to the Eagon–Northcott formula above. Therefore, by Theorem 3.3, those formulae also describe the pushforward of the virtual structure sheaf of a degeneracy locus.
3.2 Application to Vafa–Witten theory
In [GT1, GT2] it was shown how some of the monopole components of the Vafa–Witten T-fixed point set can be described as degeneracy loci, at the level of both their scheme structures and virtual cycles. We briefly review the simplest examples—2-step nested punctual Hilbert schemes of a smooth projective surface S,
For more details and more general results see [GT1, GT2].
While \(S^{[n_1,n_2]}\) is in general singular, it lies in the smooth ambient space \(S^{[n_1]}\times S^{[n_2]}\) as the set of points \((I_1,I_2)\) for which there is a nonzero map \({\text {Hom}}_S(I_1,I_2)\ne 0\). To write this scheme theoretically, let \(\pi :S^{[n_1]}\times S^{[n_2]}\times S\rightarrow S^{[n_1]}\times S^{[n_2]}\) be the projection down S, and let \({\mathcal {I}}_1,{\mathcal {I}}_2\) denote the (pullbacks of the) universal ideal sheaves on \(S^{[n_1]}\times S^{[n_2]}\times S\). Consider the complex of vector bundles
which, restricted to a point \((I_1,I_2)\), computes \({\text {Ext}}^*_S(I_1,I_2)\). When \(p_g(S)=0\) this complex can be made 2-term,Footnote 11
Then the degeneracy locus \(D(\sigma )\) is (scheme-theoretically) \(S^{[n_1,n_2]}\), and the construction (3.1) endows it with a perfect obstruction theory of dimension \(n_1+n_2\) which is independent of the choices of \(E_0,E_1\) (depending only on the K-theory class of their difference .)
By [GT1, Section 10] this perfect obstruction theory and the Vafa–Witten perfect obstruction theory of [TT1] have virtual tangent bundles which agree in K-theory.Footnote 12 Therefore the degeneracy locus virtual cycle coincides which the one coming from Vafa–Witten theory [TT1] or reduced DT theory [GSY1, GSY2] when \(h^1({\mathcal {O}}_S)=0\). And when \(h^1({\mathcal {O}}_S)>0\), the complex can be modified [GT1, Section 6], or one can work relative to \({\text {Pic}}(S)\) [GT1, Section 9], to get the same result.
The Thom–Porteous formula (3.2) then calculates the pushforward to \(S^{[n_1]}\times S^{[n_2]}\) of the Vafa–Witten virtual cycle on \(S^{[n_1,n_2]}\). In fact [GT1, GT2] deal with more complicated nested Hilbert schemes of points and curves on S. For points, the result is the following.
Theorem 3.7
[GT1] The pushforward of \(\big [S^{[n_1,n_2,\ldots ,n_r]}\big ]^{{\text {vir}}}\) to \(S^{[n_1]}\times \cdots \times S^{[n_r]}\) equals the product of Carlsson–Okounkov classes
in \(A_{n_1+n_r}\big (S^{[n_1]}\times \cdots \times S^{[n_r]}\big )\).
For the K-theoretic analogue, we assume for simplicity that \(H^{\ge 1}({\mathcal {O}}_S)=0\) so we do not have to modify the complex (3.6). Theorem 3.2 of [Th] gives a formula for any virtual structure sheaf \({\mathcal {O}}^{{\text {vir}}}_M\) which shows that it depends only on M and the K-theory class of the virtual tangent bundle \(T^{{\text {vir}}}_M\). Since the degeneracy locus construction induces the same virtual tangent bundle on \(S^{[n_1,n_2]}\) as Vafa–Witten theory, the two virtual structure sheaves induced by (2.1) are equal.
Therefore Theorem 3.3 describes the Vafa–Witten K-theoretic virtual cycle as follows.
Corollary 3.8
When \(H^{\ge 1}({\mathcal {O}}_S)=0\) the pushforward of the Vafa–Witten virtual structure sheaf \({\mathcal {O}}_{S^{[n_1,n_2]}}^{{\text {vir}}}\) to \(S^{[n_1]}\times S^{[n_2]}\) is the K-theory class of
where \(r=n_1+n_2-1\). Letting , this can be written—in topological K-theory at least—as
For a general surface S, the techniques of [GT1] can be used to split off \(H^{\ge 1}({\mathcal {O}}_S)\) from this complex. The upshot is the same result, except with the complex replaced by .
Proof
Theorem 3.3 gives the first result immediately. For the second we use [GT2, Equation 4.27], which shows the Carlsson–Okounkov K-theory class is represented by an honest rank \(r+1=n_1+n_2\) vector bundle (instead of a difference of vector bundles) on an affine bundle over \(S^{[n_1]}\times S^{[n_2]}\). Therefore, writing the pullback of as the difference of bundles \(\mathsf {CO}-{\mathcal {O}}\), we find
upstairs on the affine bundle. Since this is homotopic to the base \(S^{[n_1]}\times S^{[n_2]}\), the result follows in topological K-theory (which, by Riemann–Roch, is enough for computing holomorphic Euler characteristics). Therefore in this situation we get a more familiar Koszul resolution description of the virtual structure sheaf. \(\quad \square \)
These results can be plugged into the definition (4.3) of refined Vafa–Witten invariants below to calculate monopole locus contributions in terms of K-theory classes on smooth ambient spaces like \(S^{[n_1]}\times S^{[n_2]}\). (This requires lifts of the K-theory classes \(N^{{\text {vir}}}\) and \(K_{{\text {vir}}}^{1/2}\) (2.7) from \(S^{[n_1,n_2]}\) to \(S^{[n_1]}\times S^{[n_2]}\); these exist since they can be written in terms of the universal sheaves \({\mathcal {I}}_{{\mathcal {Z}}_1},\,{\mathcal {I}}_{{\mathcal {Z}}_1}\) and s between them, all of which extend.)
4 Refined Vafa–Witten Invariants: Stable Case
Fix a smooth complex poplarised surface \((S,{\mathcal {O}}_S(1))\), a rank \(r>0\), Chern classes \(c_1,\,c_2\) and a line bundle L on S with \(c_1(L)=c_1\). We use the notation from [TT1]; in particular \({\mathcal {N}}^\perp _{r,L,c_2}\) denotes the moduli space of Gieseker semistable Higgs pairs \((E,\phi )\) on S, where E is a rank r torsion-free sheaf on S with \(c_2(E)=c_2\) and
By the spectral construction [TT1, Section 2], \((E,\phi )\) is equivalent to a Gieseker semistable compactly supported torsion sheaf \({\mathcal {E}}_\phi \) on
This makes \({\mathcal {N}}^\perp _{r,L,c_2}\) the moduli space of Gieseker semistable compactly supported torsion sheaves \({\mathcal {E}}\) on X with the right Chern classes, such that the “centre of mass” of \({\mathcal {E}}\) on each \(K_S\) fibre of \(\rho :X\rightarrow S\) is zero, and \(\rho _*\,{\mathcal {E}}\cong L\).
When \((r,c_1,c_2)\) are chosen so that semistability implies stability,Footnote 13\({\mathcal {N}}^\perp _{r,L,c_2}\) carries a natural symmetric perfect obstruction theory [TT1, Theorem 6.1] supported in degrees \([-1,0]\). It is noncompact in general, but has a \(T={\mathbb {C}}^*\) action scaling the fibres of \(K_S\) (or, equivalently, scaling the Higgs field \(\phi \)). The fixed locus \(({\mathcal {N}}^\perp _{r,L,c_2})^T\) is compact, so in [TT1] Vafa–Witten invariants are defined by virtual (cohomological) localisation
where L is any line bundle on S with \(c_1(L)=c_1\). This lies in \({\mathbb {Q}}\subset {\mathbb {Q}}[t,t^{-1}]\) because \({\text {vd}}({\mathcal {N}}^\perp _{r,L,c_2})=0\).
The perfect obstruction theory gives us a virtual structure sheaf, and its symmetry gives us a canonical square root of the virtual canonical bundle by Proposition 2.6.
Definition 4.2
For \(r,c_1,c_2\) such that semistability implies stability, the refined Vafa–Witten invariants of \((S,{\mathcal {O}}_S(1))\) are defined by (2.20):
By Proposition 2.22 this refines (4.1), specialising to \(\mathsf {VW}_{r,c_1,c_2}\) at \(t=1\).
First fixed locus. The invariant (4.1) and its refinement (4.3) have contributions from the connected components of the fixed locus \(({\mathcal {N}}_{r,L,c_2}^\perp )^T\). The first of these is the “instanton branch” where \(\phi =0\).
This is just the moduli space \({\mathcal {M}}_{r,L,c_2}\) of stable sheaves of fixed determinant L on S. By [TT1, Equation 7.3] this locus contributes the Fantechi–Göttsche virtual signed Euler characteristic
of \({\mathcal {M}}_{r,L,c_2}\) to \(\mathsf {VW}_{r,c_1,c_2}\) (4.1). It is an integer, with an obvious refinement given (up to a sign) by the virtual \(\chi ^{}_t\)-genus of Fantechi–Göttsche [FG], as studied in [GK1]. We check now that this is what the refined Vafa–Witten invariant (4.3) indeed gives.
An open neighbourhood in \({\mathcal {N}}^\perp _{r,L,c_2}\) of the instanton branch \({\mathcal {M}}_{r,L,c_2}\) is isomorphic to its own \((-1)\)-shifted cotangent bundle \(T^*[-1]{\mathcal {M}}_{r,L,c_2}\). (It is the neighbourhood consisting of those pairs \((E,\phi )\) for which E is itself Gieseker stable. At the level of points this says that the Higgs fields take values in the dual \(({\text {Ext}}^2(E,E)_0)^*\cong {\text {Hom}}(E,E\otimes K_S)\) of the obstruction space of E.) By (2.32), then, its contribution to \(\mathsf {VW}(t)\) (4.3) is
Specialising to \(t=1\) gives
which is (4.4).
Second fixed locus. The other fixed loci have nilpotent \(\phi \ne 0\); following [DPS, GK1] we call their union \({\mathcal {M}}_2\) the “monopole branch”. For \(K_S\) negative in a suitable sense the stability condition forces the second fixed locus to be empty (a “vanishing theorem” holds). So we do some very elementary preliminary calculations on \({\mathcal {M}}_2\) for general type surfaces, refining the first calculations of [TT1, Section 8].
4.1 Some calculations for \({{\mathbf {K}}_{\mathbf {S}}}>{\mathbf {0}}\)
Let \((S,{\mathcal {O}}_S(1))\) be a smooth, connected polarised surface with
-
\(h^1({\mathcal {O}}_S)=0\), and
-
a smooth nonempty connected canonical divisor \(C\in |K_S|\), such that
-
\(L={\mathcal {O}}_S\) is the only line bundle satisfying \(0\le \deg L\le \frac{1}{2}\deg K_S\),
where degree is defined by \(\deg L=c_1(L)\cdot c_1({\mathcal {O}}_S(1))\). Then in [TT1, Lemma 8.3] it is shown that \(({\mathcal {N}}^\perp _{2,K_S,n})^T\) is the disjoint union of \({\mathcal {M}}_{2,K_S,n}\) and the nested Hilbert schemes
of subschemes \(Z_1\subseteq Z_0\subset S\) of lengths
We call the components with \(i=0\)horizontal and, at the other extreme, the components with \(i=n/2\)vertical.
Horizontal loci and \(n\le 1\)case. We start with the horizontal loci, so \(Z_1=\emptyset \) and \({\mathcal {M}}_2\cong S^{[n]}\). Here a point \(Z_0\in S^{[n]}\) corresponds in \({\mathcal {N}}^\perp _{2,K_S,n}\) to the torsion sheaf \(I_{Z_0\subset 2S}\) on \(X=K_S\), where \(2S\subset X\) is the twice-thickened zero section defined by the ideal \(I_{S\subset X}^2\). In [TT1, Section 8.2] it is shown that the fixed obstruction bundle over this \(S^{[n]}\) is \(\big (K_S^{[n]}\big )^*\). It follows that
It also follows that \({\mathcal {O}}^{{\text {vir}}}_{S^{[n]}}=\Lambda ^{\bullet }\big (K_S^{[n]}\big )\). In K-theory this has the same class as the sheaf of dgas given by inserting a differential,
where \(s\in H^0(K_S)\) cuts out the smooth connected canonical divisor \(C\subset S\) and \(s^{[n]}\) is the induced section of \(K_S^{[n]}\) on \(S^{[n]}\). Since this cuts out \(C^{[n]}\subset S^{[n]}\) which is smooth of codimension n, (4.7) is an exact Koszul resolution quasi-isomorphic to its cokernel:
Moreover the K-theory class of the virtual normal bundle is computed in [TT1, Section 8.3] to be
Here
where \(g=c_1(K_S)^2+1\) is the genus of C.
Combining (4.9) with (4.6) determines the virtual canonical bundle:
The choice (2.7) of square root is
With this, we are ready to calculate in the simplest, \(n=0,1\) and 2 cases. Even here the calculation will be somewhat involved.
\(n=0\)case. Here \({\mathcal {M}}_2\cong S^{[0]}\) is a reduced point, corresponding to the torsion sheaf \({\mathcal {O}}_{2S}:={\mathcal {O}}_X/{\mathcal {I}}_S^2\) on \(X=K_S\). From above,
Therefore we calculate the contribution of \(S^{[0]}\) to (4.3) as
where \([2]^{}_t\) is the quantum integer (1.2).
\(n=1\)case. Combining (4.10)
with (4.8) we see the contribution of \({\mathcal {M}}_2=S^{[1]}=S\) to (4.3) is
where, by (4.9),
Since \(T_S|^{}_C=T_C\oplus {\mathcal {O}}_C(C)\) in K-theory we can write
where the \((L_i,w_i)\) are
and the \((M_i,v_i)\) are
Therefore
where \(m_i:=c_1(M_i),\ \ell _i:=c_1(L_i)\) and we have repeatedly used the fact that \(m_i^2=0=\ell _i^2\) on the curve C.
Multiplying out expresses \({\text {ch}}\!\big (K_S^3\big /\Lambda ^{\bullet }(N^{{\text {vir}}})^\vee \big |_C\big ){\text {Td}}(C)\) as
Integrating over C gives \(\chi ^{}_{e^t}\). Then replacing \(e^t\) by t gives \(\chi ^{}_t\) as
Substituting (4.13), (4.14) and using \(\deg K_S|^{}_C=g-1=\deg {\mathcal {O}}_C(C)\) (by adjunction) gives
Plugging this into (4.12) gives the contribution of \({\mathcal {M}}_2\) to \(\mathsf {VW}_{2,K_S,1}(t)\) as
Horizontal \(n=2\)case; preliminaries. To calculate on \(C^{[2]}\) we fix some notation and collect some results. Let
denote the universal length-2 subscheme over \(C^{[2]}\), with projection p to C. Then \({\mathcal {Z}}\cong C\times C\) with p the projection to the first factor, while the above double cover \(q:C\times C\rightarrow C^{[2]}\) is the quotient by the \({\mathbb {Z}}/2\) action \(\tau \) swapping the factors.
Given a line bundle L on C, the induced rank 2 bundle \(L^{[2]}=q_*p^*L\) on \(C^{[2]}\) is therefore
so its pullback by \(q^*\) sits inside an exact sequence
where \(\Delta _C\subset C\times C\) is the diagonal—the branch divisor of q. But \(\tau ^*(L\boxtimes {\mathcal {O}})={\mathcal {O}}\boxtimes L\), so
The exact sequence
combined with \(\Omega _{C\times C}\cong \Omega _C\boxtimes {\mathcal {O}}_C\,\oplus \,{\mathcal {O}}_C\boxtimes \Omega _C\) and the exact sequence
gives an equality in K-theory
In particular,
As noted in (4.8), \(C^{[2]}\subset S^{[2]}\) is cut out by a transverse section \(s^{[2]}\) of \(K_S^{[2]}\), so has normal bundle \(K_S^{[2]}\big |_{C^{[2]}}=(K_S|^{}_C)^{[2]}\) and determinant
Combining this with (4.20) gives
Substituting (4.21, 4.18) into (4.10) we find
Tensoring this by (4.8) shows
where, by an abuse of notation, we are considering \({\widehat{{\mathcal {O}}}}^{\,{\text {vir}}}_{\!S^{[2]}}\) to be a sheaf on \(C^{[2]}\) (really, by (4.8), it is the K-class of the pushforward of this to \(S^{[2]}\)).
Horizontal \(n=2\)case; calculation. We wish to calculate
Let \(k:=c_1(K_C)=-c_1(C)\) and \(\chi :=2-2g=-\int _Ck=\Delta _C^2\) . Putting \(s:=e^t\), (4.22) gives
where \({\text {vol}}\) is the Poincaré dual of a point on \(C\times C\). By (4.19),
from which we can deduce
Multiplying (4.24) and (4.25) makes \({\text {ch}}\!\big (q^*{\widehat{{\mathcal {O}}}}^{\,{\text {vir}}}_{\!S^{[2]}}\big ) {\text {Td}}\!\big (q^*T_{C^{[2]}}\big )\) equal to
For the K-theory class of \(q^*\big (N^{{\text {vir}}}|_{C^{[2]}}\big )^\vee \) we use (4.9):
By (4.19) and several applications of (4.17) this is
Here we have suppressed some restrictions to C, which are easily handled using \(K_S^2\big |_C\cong K_C\). As in the last section we write this as
where \(L_i,\,M_i\) are line bundles with first Chern classes \(\ell _i,\,m_i\) respectively. Since \(\ell _i^2,\,m_i^2\) needn’t be zeroFootnote 14 on the surface \(C\times C\), (4.15) is modified to
Multiplying by \(\frac{1}{2}\)(4.26) and integrating gives \(\chi ^{}_s\) (4.23). It is the product of
and the integral over \(C\times C\) of
This integral is
From (4.27) we read off the \((\ell _i,w_i)\),
and \(P_2\) copies of \((0,-2)\). Similarly the \((m_i,v_i)\) are
and \(P_2\) copies of (0, 1). Substituting these into the integral gives
The prefactor (4.28) is
Therefore, replacing s by t, we find the contribution of \(S^{[2]}\) to the refined Vafa–Witten invariant is
At \(t=1\) this gives \((-2)^{-P_2}(1-g)(11-2g)\), as in [TT1, Equation 8.24].
Vertical \(n=2\)case. When \(n=2\) there is another component of the T-fixed locus, given by taking \(i=1\) in (4.5). This gives a copy of S, where \(x\in S\) corresponds to the sheaf
In [TT1, Section 8.7] it is shown that this T-fixed moduli space has vanishing obstruction sheaf, so that
and virtual normal bundle
In particular
whose square root (2.7) is
So the contribution of this component to the refined Vafa–Witten invariant is, by (2.14),
Using the canonical section s with zero locus C we see that in K-theory,
Therefore
while
Putting it all together gives
By Riemann–Roch \(\chi ^{}_{e^t}\) is
Let \(\kappa :=c_1(K_S)=-c_1(S)\) and \(c_2:=c_2(S)\), this is
By (4.30), therefore, the vertical contribution is
When \(\alpha ^3=0\) we compute
Similarly
Multiplying these gives
Now \(\big (1-{\text {ch}}(\Omega _S)t^2+e^{\kappa }t^4\big )\!{\text {Td}}_S\) is
Plugging all this into (4.31) gives \(t^{-2}(-[2]^{}_t)^{-P_2}\) times by
So the vertical contribution to the refined Vafa–Witten invariant is
Setting \(t=1\) gives \((-2)^{-P_2}\big (6(g-1)+c_2)\) in agreement with [TT1, Equation 8.28].
Total. Adding this to the horizontal contribution (4.29) at \(n=2\) gives a total
Combining this with (4.11) and (4.16) gives the generating series
Many thanks to Martijn Kool who pointed out this formula perfectly matches the first few terms of calculations of Göttsche–Kool [GK1] after applying the most naive modularity transformation. Specialising to \(t=1\) gives
as in [TT1, Equation 8.39], or indeed the second term of the first line of [VW, Equation 5.38].
For higher \(c_2\) we need a more systematic way to compute. Laarakker [La1] combines the degeneracy locus description of monopole branches in [GT1] and Sect. 3 of this paper with cobordism arguments to prove universality results. This also translates computations to calculations on toric surfaces, which can be done by localisation and computer for \(c_2\) not too large.
5 Refined Vafa–Witten Invariants: Semistable Case
As before we fix a polarised surface \((S,{\mathcal {O}}_S(1))\). Pulling back gives a polarisation \({\mathcal {O}}_X(1)\) on the local Calabi-Yau threefold \(X=K_S\). We define the charge of a compactly supported coherent sheaf \({\mathcal {E}}\) on X to be the total Chern class
of the pushdown \(E=\rho _*\,{\mathcal {E}}\) on S. Given \(n\gg 0\) and \(L\in {\text {Pic}}_{c_1}(S)\), an SU(r)-Joyce–Song pair \(({\mathcal {E}},s)\) consists of
-
a compactly supported coherent sheaf \({\mathcal {E}}\) of charge \(\alpha \) on X, with centre-of-mass zero on each fibre of \(\rho :X\rightarrow S\) and \(\det \rho _*\,{\mathcal {E}}\cong L\), and
-
a nonzero section \(s\in H^0({\mathcal {E}}(n))\).
Equivalently, it is a triple \((E,\phi ,s)\) on S with \(\phi \in {\text {Hom}}(E,E\otimes K_S)^{}_0,\ \det E\cong L\) and \(s\in H^0(E(n))\). The Joyce–Song pair \(({\mathcal {E}},s)\) is stable if and only if
-
\({\mathcal {E}}\) is Gieseker semistable with respect to \({\mathcal {O}}_X(1)\), and
-
if \({\mathcal {F}}\subset {\mathcal {E}}\) is a proper subsheaf which destabilises \({\mathcal {E}}\), then s does not factor through \({\mathcal {F}}(n)\subset {\mathcal {E}}(n)\).
For fixed \(\alpha \) we may choose \(n\gg 0\) such that \(H^{\ge 1}({\mathcal {E}}(n))=0\) for all Joyce–Song stable pairs \(({\mathcal {E}},s)\). There is no notion of semistability; there is a quasi-projective moduli scheme \({\mathcal {P}}^\perp _{\alpha ,n}\) of stable Joyce–Song pairs whose \(T={\mathbb {C}}^*\)-fixed locus is already compact.
Most importantly, \({\mathcal {P}}^\perp _{\alpha ,n}\) can be shown to be a moduli space of complexes \(I^{\bullet }:=\{{\mathcal {O}}_X(-n)\rightarrow {\mathcal {E}}\}\) with a symmetric perfect obstruction theory governed by \(R{\text {Hom}}(I^{\bullet },I^{\bullet })^{}_\perp \). As a result it inherits a virtual structure sheaf and the virtual canonical bundle admits a canonical square root (2.7) on the T-fixed locus. Thus by (2.20) we get a refined pairs invariant
Using the quantum integers defined in (1.2),
(which specialise to n at \(q=1\)) we can state the refined version of [TT2, Conjecture 6.5].
Conjecture 5.2
Suppose \({\mathcal {O}}_S(1)\) is generic for charge \(\alpha \) in the sense of [TT2, Equation 2.4].Footnote 15 If \(H^{0,1}(S)=0=H^{0,2}(S)\) there exist \(\mathsf {VW}_{\alpha _i}(t)\in {\mathbb {Q}}(t^{1/2})\) such that
for \(n\gg 0\). When either of \(H^{0,1}(S)\) or \(H^{0,2}(S)\) is nonzero we take only the first term in the sum:
The first justification for this Conjecture is that it specialises at \(t=1\) to Conjecture 6.5 of [TT2], which is proved in many cases [MT1, TT2]. Therefore, when the Conjecture holds, the resulting \(\mathsf {VW}_\alpha (t)\) specialise at \(t=1\) to the numerical Vafa–Witten invariants of [TT2].
As a second sanity check, we show it is true—and reproduces the earlier Definition 4.2 of refined Vafa–Witten invariants—when there are no strictly semistable sheaves.
Proposition 5.5
If all semistable sheaves in \({\mathcal {N}}_\alpha ^\perp \) are stable then Conjecture 5.2 is true with the coefficients \(\mathsf {VW}_\alpha (t)\) given by (4.3).
Proof
We adapt the proof of the corresponding result for numerical Vafa–Witten invariants in [TT2, Proposition 6.8].
We proceed by induction on the rank r of \(\alpha =(r,c_1,c_2)\). We first claim that if there are no strictly semistables in class \(\alpha \) then only the first term contributes to the sum (2.24). Indeed, if there was a nonzero contribution indexed by \(\alpha _1,\ldots ,\alpha _\ell \) with \(\ell >1\) then the nonvanishing of the coefficients \(\mathsf {VW}_{\alpha _i}(t)\) (which equal the refined Vafa–Witten invariants (4.3) by the induction hypothesis) would imply that the moduli spaces \({\mathcal {N}}^\perp _{\alpha _i}\) are nonempty. Picking an element \({\mathcal {E}}^i\) of each defines a strictly semistable \({\mathcal {E}}:={\mathcal {E}}^1\oplus \cdots \oplus {\mathcal {E}}^\ell \) of \({\mathcal {N}}_\alpha ^\perp \), a contradiction.
We use the smooth \({\mathbb {P}}^{\chi (\alpha (n))-1}\)-bundle
where is the (possibly twisted) universal sheaf on \({\mathcal {N}}_\alpha ^\perp \times X\) and \(\pi :{\mathcal {N}}^\perp _\alpha \times X\rightarrow {\mathcal {N}}_\alpha \). There is a corresponding relationship between the deformation-obstruction theories of \(({\mathcal {N}}_\alpha ^\perp )^T\) and \(({\mathcal {P}}_{\alpha ,n}^\perp )^T\) worked out in [TT2, Equations 6.12–6.14]. In particular [TT2, Equation 6.13] implies that the virtual structure sheaves of their T-fixed loci satisfy
where \(T_p\) is the relative tangent bundle of p. And by [TT2, Equation 6.14] their dual virtual normal bundles are related by
Taking the determinant of [TT2, Equation 6.12] gives, by (2.7),
Putting it all together we have
by the identity (2.28) applied to \(T_p\otimes {\mathfrak {t}}^{-1}\). To take \(\chi ^{}_t\) we first push down the restriction of p to \(({\mathcal {P}}_{\alpha ,n}^\perp )^T\rightarrow ({\mathcal {N}}^\perp _\alpha )^T\). This is a smooth bundle; on each fibre we get
where \({\mathbb {P}}={\mathbb {P}}^{\chi (\alpha (n))-1}\) is acted on by T with fixed locus \({\mathbb {P}}\,^T\). We recognise (5.6) as the computation of
by localisation to the fixed locus \({\mathbb {P}}\,^T\). (Here we have used the fact that T acts trivially on \(H^i(\Omega ^j_{{\mathbb {P}}}))\) since the latter is topological.) Moreover, there is no twisting as we move over the base—the fibrewise cohomology groups of a \({\mathbb {P}}^{\chi (\alpha (n))-1}\) bundle are canonically trivialised by powers of the hyperplane class.Footnote 16 So the upshot is
in K-theory. Taking \(\chi ^{}_t\) gives
\(\square \)
5.1 deg \({\mathbf {K}}_{\mathbf {S}}<{\mathbf {0}}\): refined DT invariants
When \(\deg K_S<0\) the moduli space \({\mathcal {P}}^\perp _{\alpha ,n}\) of Joyce–Song pairs on X is smooth [TT2, Section 6.1] and consists entirely of pairs pushed forward (scheme theoretically) from S. The obstruction bundle is \(T^*_{{\mathcal {P}}^\perp _{\alpha ,n}}\otimes {\mathfrak {t}}\). It follows from Proposition 2.31 that the refined pairs invariant is
The Vafa–Witten obstruction theory on \({\mathcal {P}}^\perp _{\alpha ,n}\) is the DT obstruction theory of [JS] since \(H^1({\mathcal {O}}_S)=0=H^2({\mathcal {O}}_S)\). So we can expect the refined Vafa–Witten invariants to be closely related to refined DT invariants,Footnote 17 and this is what we will find.
We use Joyce’s Ringel-Hall algebra for \(\mathrm {Coh}(S)\) constructed in [Jo2]. Joyce starts with the \({\mathbb {Q}}\)-vector space on generators given by (isomorphism classes of) representable morphisms of stacks from algebraic stacks of finite type over \({\mathbb {C}}\) with affine stabilisers to the stack of objects of Coh(S). He then quotients out by the scissor relations for closed substacks, and makes the result into a ring with his Hall algebra product \(*\) on stack functions.
At the level of individual objects, the product \(1_E*1_F\) of (the indicator functions of) E and F is the stack of all extensions between them,
with \(e\in {\text {Ext}}^1(F,E)\) mapping to the corresponding extension of F by E. More generally \(*\) is defined via the stack \(\mathfrak {Ext}\) of all short exact sequences
in Coh(S), with its morphisms \(\pi _1,\pi ,\pi _2:\mathfrak {Ext}\rightarrow \) Coh(S) taking the extension to \(E_1,\,E,\,E_2\) respectively. This defines the universal case, which is the Hall algebra product of Coh(S) with itself:
Other products are defined by fibre product with this: given two stack functions \(U,V\rightarrow \) Coh(S) we define \(U*V\rightarrow \) Coh(S) by the Cartesian square
We are interested in the elements
where \({\mathcal {M}}^{ss}_\alpha \) is the stack of Gieseker semistable sheaves of class \(\alpha \) on \((S,{\mathcal {O}}_S(1))\), and \(1_{{\mathcal {M}}^{ss}_\alpha }\) is its inclusion into the stack of all sheaves on S. To handle the stabilisers of strictly semistable sheaves, Joyce replaces these indicator stack functions by their “logarithm": the following (finite!) sum:
Here \(p_\alpha \) denotes the reduced Hilbert polynomial of sheaves of class \(\alpha \).
A deep result of Joyce [Jo3, Theorem 8.7] is that the logarithm (5.12) lies in the set of virtually indecomposable stack functions with algebra stabilisers,
By [JS, Proposition 3.4] this means it can be written as a \({\mathbb {Q}}\)-linear combination of morphisms from stacks of the form
Now all moduli stacks of semistable torsion free sheaves on S of class \(\alpha \) are smooth of dimension \(-\chi ^{}_S(\alpha ,\alpha )\), since any obstruction space \({\text {Ext}}^2(E,E)\) is Serre dual to \({\text {Hom}}(E,E\otimes K_S)\), which vanishes by the semistability of E and the negativity of \(\deg K_S\). Therefore we do not have to worry about vanishing cycles or orientation data; we can make a naive definition of the Joycian refined DT invariantFootnote 18 by taking the normalised Hirzebruch \(\chi ^{}_{-t}\)-genus of the (\({\mathbb {Q}}\)-linear combination of) stacks \(\epsilon _\alpha \):
The factor \((t-1)\) is there to cancel the \({\mathbb {C}}^*\) stabilisers in (5.13). Joyce’s result that \(\epsilon _\alpha \) is a virtual indecomposable therefore means that \({\mathsf {J}}_\alpha (t)\) has a finite limit as \(t\rightarrow 1\); this limit is the numerical DT invariant.
We can use this to prove a refined version of the Joyce–Song identity [JS, Theorem 5.27], and hence our Conjecture 5.2, when \(\deg K_S<0\).
Theorem 5.15
If \(\deg K_S<0\) and \({\mathcal {O}}_S(1)\) is generic then
Since \(H^1({\mathcal {O}}_S)=0=H^2({\mathcal {O}}_S)\) this shows that Conjecture 5.2 holds, with the refined Vafa–Witten invariants equalling the refined DT invariants
Here, as before (1.2), \([\chi (\alpha (n))]_t\) is the symmetrised Poincaré polynomial (or Hirzebruch \(\chi ^{}_{-t}\) genus) of \({\mathbb {P}}(H^0(E(n)))\) for any sheaf E of charge \(\alpha \). This refines the Euler characteristic \(\chi (\alpha (n))\) of \({\mathbb {P}}(H^0({\mathcal {E}}(n)))\) that appears in [JS, Theorem 5.27].
Because the Vafa–Witten perfect obstruction theory coincides with the DT obstruction theory when \(H^1({\mathcal {O}}_S)=0=H^2({\mathcal {O}}_S)\), this theorem is an instance of Maulik’s result [Ma] that, for some local Calabi-Yaus, the refinement of Joyce/Kontsevich-Soibelman coincides with the refinement of Nekrasov-Okounkov.
Proof
We follow [JS, Chapter 13], fixing \(n\gg 0\) and use the same auxiliary categories \({\mathcal {B}}_{p_\alpha }\) (whose objects are Gieseker semistable sheaves E on S with reduced Hilbert polynomial a multiple of \(p_\alpha \), plus a vector space V and a linear map \(V\rightarrow H^0(E(n))\)) with K-theory classes in \(K(\mathrm {Coh}(S))\oplus {\mathbb {Z}}\). We use the Euler form \({\bar{\chi }}\big ((\alpha ,d),(\beta ,e)\big ):=\chi ^{}_S(\alpha ,\beta )-d\chi (\alpha (n))-e\chi (\beta (n))+de\chi ({\mathcal {O}}_S)\). Gieseker stability on Coh(S) induces stability conditions on \({\mathcal {B}}_{p_\alpha }\). Wall crossing between them gives the following identity of stack functions [JS, Proposition 13.10]Footnote 19
Here the Lie bracket is with respect to the Hall algebra product on stack functions, and \(\epsilon _\alpha \) is the stack function (5.12) mapping to the stack of semistable sheaves in Coh(S) thought of as semistable objects in \({\mathcal {B}}_{p_\alpha }\). Then \(\epsilon ^{(\alpha ,1)}\) is defined in a similar way from objects in \({\mathcal {B}}_{p_\alpha }\) (with the K-theory class of \({\mathcal {O}}(-n)\rightarrow E\), for E of class \(\alpha \)) which are semistable with respect to Joyce–Song’s stability condition \({\tilde{\tau }}\). As in [JS, 13.5], it is the stack \({\mathcal {P}}^\perp _{\alpha ,n}/{\mathbb {C}}^*\).
Set \(\alpha _{<k}:=\alpha _1+\ldots +\alpha _{k-1}\) and \(\alpha _{\le k}:=\alpha _1+\ldots +\alpha _k\). We multiply out the Lie brackets in (5.16), starting with the innermost one. We claim that by induction, at the k th stage, we get a bracket
where \(A^{(\alpha _{<k},1)}\) maps to the stack of semistable objects A of \({\mathcal {B}}_{p_\alpha }\) which have charge \((\alpha _{<k},1)\). Let E be any semistable object of \({\mathcal {B}}_{p_\alpha }\) of charge \((\alpha _k,0)\) (i.e. semistable sheaf on S of charge \(\alpha _k\)).
All extensions from E to F or from F to E giving semistable objects of \({\mathcal {B}}_{p_\alpha }\) of charge \((\alpha _{\le k},1)\). Therefore (5.17) maps to the stack of semistable objects of \({\mathcal {B}}_{p_\alpha }\) of charge \((\alpha _{\le k},1)\), and the induction continues. Moreover,
with no other Exts, and
also with no further Exts. Therefore by the scissor relations and (5.9) (in constructible families) we have
as a \({\mathbb {Q}}\)-linear combination of stacks. Since all \(\alpha _i=\delta _i\alpha \) are proportional to \(\alpha \) we see that \(\chi ^{}_S(\alpha _{<k},\alpha _k)\) is symmetric in its arguments, and
Therefore the Lie brackets in (5.16) give in total
where the final term comes from \(\epsilon ^{(0,1)}\cong B{\mathbb {C}}^*\). Taking \((t-1)\chi ^{}_{-t}\) of this gives, by (5.14),
By expressing \(\chi ^{}_S(\alpha ,\alpha )\) as
this can be rewritten
Therefore \((t-1)\chi ^{}_{-t}(\ \cdot \ )\) applied to (5.16) gives
Multiplying both sides by \((-1)^{\dim {\mathcal {P}}^\perp _{\alpha ,n}}t^{-\frac{1}{2}\dim {\mathcal {P}}^\perp _{\alpha ,n}}\) gives, by (5.8),
which is the result claimed. \(\quad \square \)
5.2 \({{\mathbf{p}}_{\mathbf{g(S)}}>{\mathbf{0}}}\) cosection and vanishing theorem
Fix a surface S with \(p_g(S)>0\). In his calculations [La1] Ties Laarakker observed a certain vanishing (more-or-less Corollary 5.30 below, in low ranks). Here we explain it by describing a certain cosection of the fixed obstruction theory, on any connected component \({\mathcal {P}}\) of the monopole branch of the T-fixed loci \(({\mathcal {P}}^\perp _{\alpha ,n})^T\). If stable\(\,=\,\)semistable the same construction can be done with moduli spaces \({\mathcal {N}}\subset ({\mathcal {N}}^\perp _\alpha )^T\) of sheaves on X (or Higgs pairs on S) instead.
The construction is basically the same as in [PT, Section 5]; we simply replace stable pairs by Joyce–Song pairs and impose the centre-of-mass-zero conditionFootnote 20 on each \({\mathbb {C}}\) fibre of \(X=S\times {\mathbb {C}}\) (equivalently, the \({\text {tr}}\phi =0\) condition on the Higgs field).
We find it convenient to describe the cosection using Higgs data on S. For a more geometric description using sheaves on X instead, see [PT, Section 5]. By the symmetry of the obstruction theory, what we require is a T-weight one \({\mathcal {P}}^\perp _{\alpha ,n}\) vector field along (but not tangent to) \({\mathcal {P}}\). This is Serre dual to a weight zero (i.e. invariant) cosection of the obstruction sheaf.
Since Joyce–Song stable pairs have no automorphisms and form a fine moduli space, there is a universal Higgs pair and Joyce–Song section \(({\mathsf {E}},\Phi ,{\mathsf {s}})\) over the total space of \(p^{}_S:S\times {\mathcal {P}}\rightarrow {\mathcal {P}}\). Thus
where \(n\gg 0\) is sufficiently large that \({\mathsf {E}}(n)\) has no higher cohomology on any S fibre.
Furthermore this lack of automorphisms means the universal T-fixed sheaf \({\mathsf {E}}\) admits a T-linearisation. (For any \(\lambda \in T\) we get a unique isomorphism \(\phi _\lambda :(E,\phi ,s)\rightarrow \lambda ^*(E,\phi ,s)=(E,\lambda \phi ,s)\). Uniqueness then implies that \(\phi _\lambda \circ \phi _\mu =\phi _{\lambda \mu }\).) Tensoring by its highest weight, we may assume that
with each of \({\mathsf {E}}_0\) and \({\mathsf {E}}_{r-1}\)nonzero and all \({\mathsf {E}}_i\) flat over \({\mathcal {P}}\). Since we are on the monopole branch, \(r\ge 2\). The weight one \(\Phi \) maps each \({\mathsf {E}}_i\) to \({\mathsf {E}}_{i+1}\), and \({\mathsf {s}}\) is T-fixed up to automorphisms of \({\mathsf {E}}\).
Fix a nonzero holomorphic 2-form
and consider the trace-free endomorphism
It defines a family of Higgs triplesFootnote 21
where t is the parameter on \({\mathbb {C}}={\mathbb {C}}_t\). This family is classified by a map
Differentiating at \(t=0\) (equivalently, restricting from \({\mathbb {C}}_t\) to \({\text {Spec}}\,{\mathbb {C}}[t]/(t^2)\)) we get a \({\mathcal {P}}^\perp _{\alpha ,n}\) vector field on \({\mathcal {P}}\),
By construction it has T weight one. The symmetry of the obstruction theory
makes \(\Omega _{{\mathcal {P}}}\cong \mathrm {Ob}_{\,{\mathcal {P}}}\otimes {\mathfrak {t}}^{-1}\), so (5.21) is equivalent to a weight zero cosection
Its image is an ideal sheaf
so (5.22) has a well-defined zero scheme \(Z({\dot{\varphi }})\).
Theorem 5.23
Pick \(0\ne \sigma \in H^{2,0}(S)\) and consider the cosection (5.22) on a connected component \({\mathcal {P}}\subset ({\mathcal {P}}^\perp _{\alpha ,n})^T\) of the monopole branch.
At any closed point of the zero scheme \(Z({\dot{\varphi }})\subset {\mathcal {P}}\) the maps \(\phi :E_i\rightarrow E_{i+1}\) are both injective and generically surjectiveFootnote 22 on S for each \(i=0,\ldots ,r-2\). In particular if \(Z({\dot{\varphi }})\ne \emptyset \) then \({\text {rank}}{\mathsf {E}}_0={\text {rank}}{\mathsf {E}}_1=\cdots ={\text {rank}}{\mathsf {E}}_{r-1}\).
Proof
First we discuss how basechange works in this setting. If \(p=(E,\phi ,s)\) is a point of \({\mathcal {P}}\) with ideal \({\mathfrak {m}}\subset {\mathcal {O}}_{{\mathcal {P}}}\) then \(\Omega _{{\mathcal {P}}}|_p\cong {\mathfrak {m}}/{\mathfrak {m}}^2\) and (5.22) induces a map \({\mathfrak {m}}/{\mathfrak {m}}^2\rightarrow {\mathcal {O}}_p\cong {\mathbb {C}}\) which is zero if and only if \(p\in Z({\dot{\varphi }})\). Therefore \(p\in Z({\dot{\varphi }})\) if and only if the vector field (5.21) restricted to p maps to zero under the natural map (which need not be an isomorphism!)
But \(\big ({\mathfrak {m}}/{\mathfrak {m}}^2\big )^*\) is described by deformation theory [TT2] as \({\text {Ext}}^1_X(I^{\bullet },I^{\bullet })^{}_\perp \). By forgetting the section s, this maps (see [TT2, Equation 6.11], for instance)
to the first order deformation space of \((E,\phi )\), which sits in the exact sequence
of [TT1, Equations 2.20 and 5.32]. By (5.19) the image of the vector field (5.21) under first (5.24) and then (5.25) can be seen in this exact sequence as the image of
in the second term. So to prove that \(p\not \in Z({\dot{\varphi }})\) it is sufficient to show that (5.27) is not in the image of the first term of the sequence (5.26).
Assume first that at the point \(p=(E=\oplus _{i=0}^{r-1}E_i{\mathfrak {t}}^{-i},\phi ,s)\in {\mathcal {P}}\), one of the \(\phi :E_i\rightarrow E_{i+1}\) fails to be injective on S. Letting \(K_i\) denote the kernel of
our assumption is that
Since \((E,\phi )\) is semistable it is torsion free, so all of the \(K_i\subset E_i\) are torsion free. There is an open subset \(U\subset S\) over which they are all locally free, \(\phi \) has constant rank, and—we claim—there is a \(\phi \)-invariant splitting
To prove the claim, we may shrink U if necessary and then split \(K_0\subset E_0\) over it. Then we proceed inductively. At the ith stage we have split \(E_i=K_i\oplus E_i/K_i\) over U, which we use to form \(\phi (E_i/K_i)\subset E_{i+1}\). Since its intersection with \(K_{i+1}\subset E_{i+1}\) is 0 we have \(\phi (E_i/K_i)\oplus K_{i+1}\subset E_{i+1}\). Further shrinking U if necessary we can find a complement \(C_i\) to this subbundle. Then \(C_i\oplus \phi (E_i/K_i)\) gives the required complement to \(K_{i+1}\subset E_{i+1}\).
Therefore (5.29) defines a local splitting of Higgs bundles over U. The endomorphism \({\dot{\varphi }}|_U\) of (5.27) acts on the first summand as
Therefore it is not in the image of the map \([\ \cdot \ ,\phi ]\) in the sequence (5.26), since commutators are trace-free. That is, it defines a nonzero deformation of the Higgs pair \((K,\phi |_K)\) over U. Therefore the cosection (5.22) is nonzero at p.
So now we turn to the case where \(K=0\) but at least one of the maps (5.28) has cokernel of rank \(>0\). Then there is an open set \(U\subset S\) over which the cokernels are locally free, \({\text {rank}}(\phi )\) is constant, and—we claim—there is a \(\phi \)-invariant splitting of locally free sheaves
with \(C_{k-1}\ne 0\). We prove the claim inductively, with base case \(C_0:=0\). At the ith stage, possibly after shrinking U as usual, we pick a complement \(D_{i+1}\) to \(\phi ^{i+1}(E_0)\) and then set \(C_{i+1}=D_{i+1}\oplus \phi (C_i)\).
Therefore \(\bigoplus _{i=0}^{k-1}\phi ^iE_0|_U\) is a proper sub Higgs bundle of \((E,\phi )|_U\). On restriction to it, the endomorphism (5.27) acts as
whose trace is \(<{\text {rank}}(\phi ^{k-1}(E_0))-{\text {rank}}(E_{k-1})=-{\text {rank}}(C_{k-1})<0\). Therefore it is not in the image of the map \([\ \cdot \ ,\phi ]\) in the sequence (5.26). That is, it defines a nonzero deformation of the sub Higgs bundle over U, and again the cosection (5.22) nonzero at \(p=(E,\phi ,s)\). \(\quad \square \)
These results can be strengthened, for instance by showing that at points of \(Z({\dot{\varphi }})\) the cokernels of \(\phi :E_i\rightarrow E_{i+1}\) must have support on the zero divisor of \(\sigma \)—see Theorem 5.34 below for K3 surfaces, for example. But since a nowhere zero cosection on \({\mathcal {P}}\) forces its contribution to the K-theoretic invariant to vanish (by an easy special case of [KL]; see for instance [KL, Proposition 3.2]) the above result is enough to prove that most components \({\mathcal {P}}\) do not contribute to the invariants. In particular the most obvious special case is the following.
Corollary 5.30
If \(h^{2,0}(S)>0\) and the multi-rank is non-constant,
then \({\mathcal {P}}\) does not contribute to the refined invariants.
Remark 5.31
The cosection does not rule out the contribution of all components. For instance, when \(\Phi :{\mathsf {E}}_i\rightarrow {\mathsf {E}}_{i+1}\) is an isomorphism for \(i=0,\ldots ,r-2\), the cosection (5.22) vanishes identically. This is because the endomorphism (5.19) can be written
where \(A:{\mathsf {E}}\rightarrow {\mathsf {E}}\) acts as zero on \({\mathsf {E}}_0\) and as \(\Phi ^{-1}:{\mathsf {E}}_i\rightarrow {\mathsf {E}}_{i-1}\) on any other summand. Therefore, in the exact sequence
of [TT1, Equations 2.20 and 5.32], we see that \({\dot{\varphi }}\) maps to zero in the deformation space of on \(p^{}_X:X\times {\mathcal {P}}\rightarrow {\mathcal {P}}\). That is, the first order deformation of (or equivalently \(({\mathsf {E}},\Phi )\)) is zero. Since \({\mathsf {s}}\) is constant in the flow (5.20), we see the tangent vector (5.21) vanishes identically so \(Z({\dot{\varphi }})={\mathcal {P}}\).
5.3 K3 surfaces
The cosection (5.22) gives the strongest results on (polarised) K3 surfaces \((S,{\mathcal {O}}_S(1))\). Just as for the stable pairs in [PT], it will show that the only Joyce–Song pairs on \(S\times {\mathbb {C}}\) which contribute nontrivially to the refined Vafa–Witten invariants are those which have constant thickening in the \({\mathbb {C}}\)-direction. That is, they are pulled back from S then tensored by \({\mathcal {O}}_{rS}:={\mathcal {O}}_X/I_{S\subset X}^r\) for some \(r>0\):
In Higgs language these correspond to the following.
Definition 5.33
We call a point \((E,\phi ,s)\in ({\mathcal {P}}^\perp _{\alpha ,n})^T\)uniform if the maps (5.28) are all isomorphisms. Equivalently,
Theorem 5.34
A connected component \({\mathcal {P}}\subset ({\mathcal {P}}^\perp _{\alpha ,n})^T\) contains a uniform point if and only if all its points are uniform, if and only if the cosection (5.22) vanishes identically on \({\mathcal {P}}\).
Otherwise the cosection is nowhere zero on \({\mathcal {P}}\). In particular, non-uniform components \({\mathcal {P}}\) contribute zero to the refined invariants.
Proof
Firstly we claim that for any semistable Higgs pair \((E,\phi )\) on S the underlying sheaf E is also semistable.
Let \(F\subset E\) be the first term of its Harder-Narasimhan filtration. Therefore F is semistable with strictly larger reduced Hilbert polynomial (or “Gieseker slope") than the other graded pieces of the filtration. Since those pieces are also semistable, it follows that
Therefore the Higgs field \(\phi \) preserves F, so F either strictly destabilises \((E,\phi )\) or is all of E.
In particular each \(E_i\) in the weight space decomposition of E is semistable (and so torsion-free) of the same reduced Hilbert polynomial. Therefore if \(\phi :E_i\rightarrow E_{i+1}\) is injective and generically surjective, it is an isomorphism.
It therefore follows from Theorem 5.23 that any closed point of the zero locus \(Z({\dot{\varphi }})\) of the cosection is uniform in the sense of Definition 5.33. Since being uniform is an open condition, while the zero locus \(Z({\dot{\varphi }})\) is closed, a single uniform point makes the whole connected component \({\mathcal {P}}\) uniform. In this case the cosection vanishes identically on \({\mathcal {P}}\) by Remark 5.31. \(\quad \square \)
5.4 Refined multiple cover formula
When \({\mathcal {O}}_S(1)\) is generic for charge \(\alpha \) this leaves only the uniform components to calculate on:
Here \({\mathcal {P}}^\perp _{\left( \frac{\alpha }{r}\right) ^{\!\,r}\!,\,n}\) is the moduli space of uniform Joyce–Song pairs of charge \(\alpha \) which are r-times thickened pairs of charge \(\alpha /r\). They are determined by their restriction to S, giving an isomorphism
Here \({\mathcal {P}}^S_{\alpha /r,n}\) denotes the moduli space of Joyce–Song stable pairs (E, s) on \((S,{\mathcal {O}}_S(1))\) with charge \(\alpha /r\): so E is a Gieseker semistable sheaf on S with total Chern class \(\alpha /r\), and \(s\in H^0(E(n))\) does not factor through any destabilising subsheaf of E. We noted in Theorem 5.34 this gives a bijection of sets. That this makes \({\mathcal {P}}^S_{\alpha /r,n}\)scheme theoretically isomorphic to a component of \(({\mathcal {P}}^\perp _{\alpha ,n})^T\) follows from the the deformation theory analysis (5.36) below, or by [PT, Lemma 1].
Fix r and let \(\alpha _0=\alpha /r\). Both \({\mathcal {P}}^S:={\mathcal {P}}^S_{\alpha _0,n}\) and \(({\mathcal {P}}^\perp _{r\alpha _0,n})^T\) are fine moduli spaces. We denote the two universal sheaves by
and the universal complexes made from the Joyce–Song pairs by
with \({\mathcal {O}}(-n)\) in degree 0. As usual \(p^{}_S:S\times {\mathcal {P}}^S\rightarrow {\mathcal {P}}^S\) and \(p^{}_X:X\times {\mathcal {P}}^S\rightarrow {\mathcal {P}}^S\) denote the projections. Now let
Though we will not need to know it, this is the virtual cotangent bundle of the natural perfect obstruction theory on the moduli space \({\mathcal {P}}^S\) of pairs on S; see [KT1] for instance.
When considered instead as a moduli space of sheaves on X (not yet imposing the centre-of-mass-zero condition), we get a the virtual cotangent bundle
by [PT, Proposition 4]. (While that paper works with stable pairs, it uses none of their special properties—the proof goes through verbatim for Joyce–Song pairs.)
To get the Vafa–Witten obstruction theory we remove \(H^0(K_S)\otimes {\mathfrak {t}}\) from the deformations (imposing the centre-of-mass-zero condition) and—dually—\(H^2({\mathcal {O}}_S)\) from the obstructions, replacing \(E_S^{\bullet }\) by the reduced obstruction theory of [KT1] (we do not prove this compatibility of obstruction theories since we do not need it; we only require the K-theory class of the virtual (co)tangent bundle). The upshot is that the Vafa–Witten obstruction theory of [TT2] is, on restriction to \({\mathcal {P}}^S\subset {\mathcal {P}}^\perp _{r\alpha _0,n\,}\), the K-theory class of
If we write
then
From this we read off
where \({\text {vd}}:={\text {rank}}({\mathbb {L}}^{{\text {red}}}_S)\) is the reduced virtual dimension of \({\mathcal {P}}^S\),
and
Therefore
by two applications of the identity \(\det (E)^*\otimes \Lambda ^{\bullet }E\big /\Lambda ^{\bullet }E^\vee =(-1)^{{\text {rank}}(E)}\) of (2.28).
Substituting \({\text {rank}}(\Psi )=(r-1){\text {vd}}-(r-2)\) and \({\text {vd}}\equiv \chi (\alpha _0(n))-1\pmod 2\) and taking \(\chi ^{}_t\) gives the following contribution to the refined pairs invariants,
cf. (2.32). This gives a refined multiple cover formula under any of the conditions
-
(1)
\(\alpha _0=\alpha /r\) is primitive, or
-
(2)
all semistable sheaves of class \(\alpha _0\) on S are stable, or
-
(3)
Conjecture 5.2 holds for \(\alpha _0\).
Notice that \((1)\Rightarrow (2)\) while Proposition 5.5 shows \((2)\Rightarrow (3)\).
Theorem 5.38
Suppose any of (1), (2) or (3) holds for the charge \(\alpha _0\). Then the contribution (5.37) of uniform Joyce–Song pairs satisfies Conjecture 5.2 for all r. The resulting refined Vafa–Witten invariants are given by the multiple cover formula
Furthermore, when \(\alpha _0\) is primitive, setting \(d:=1-\frac{1}{2}\chi ^{}_S(\alpha _0,\alpha _0)\) we have
Proof
Since we are assuming Conjecture 5.2 holds for \(\alpha _0\), we may apply (5.4) to the \(r=1\) instance of (5.37) to deduce
Combining this with the identity \([\chi ]^{}_{t^r}[r]^{}_t=[r\chi ]^{}_t\), we rewrite (5.37) as
Therefore (5.4) holds for all \(k>1\) with
When \(\alpha _0\) is primitive, \({\mathcal {P}}^S={\mathcal {P}}^S_{\alpha ^{}_0,n}\) is a \({\mathbb {P}}^{\chi (\alpha _0(n))-1}\)-bundle over the moduli space \({\mathcal {M}}_S\) of (semistable\(\,=\,\)stable) sheaves on S of class \(\alpha _0\). In turn, \({\mathcal {M}}_S\) is smooth with \({\mathbb {L}}^{{\text {red}}}_S\cong \Omega _{{\mathcal {M}}_S}\) and deformation equivalent to \({\text {Hilb}}^dS\), where \(d=1-\frac{1}{2}\chi ^{}_S(\alpha _0,\alpha _0)\). So pushing \(\Lambda ^{\bullet }(\Omega _{{\mathcal {P}}^S}{\mathfrak {t}})\) down to \({\mathcal {M}}_S\) and then taking \(\chi ^{}_t\) gives, just as in (5.7),
Substituting this into (5.40) gives
\(\square \)
So (5.39) turns out to be the correct refinement of the more familiar multiple cover formula
For these numerical invariants it is known (by a results of [MT1, PT, To] combined in [TT2, Theorem 6.21]) that
even when \(\alpha _0\) is not primitive. That is, the contribution of T-fixed semistable sheaves scheme theoretically supported on S to the Vafa–Witten invariants is what we get for primitive \(\alpha _0\).
It seems natural to conjecture the same for the refined invariants. Summing over all uniform multiple covers using (5.35),
then substituting in (5.39) gives the following.
Conjecture 5.43
If \({\mathcal {O}}_S(1)\) is generic in the sense of [TT2, Equation 2.4] then
When \(\alpha =r\alpha _0\) with r prime and \(\alpha _0\) primitive, this was already conjectured by Göttsche–Kool [GK3]. But by (5.42) and Theorem 5.38, we have proved this to be true.
Theorem 5.44
If \({\mathcal {O}}_S(1)\) is generic, \(\alpha \) is primitive and r is prime then Conjecture 5.43 is true:
\(\square \)
Taking \(\alpha =(r,0,k)\) in the general case of Conjecture 5.43, in terms of generating series it says
where on the right we have summed over those second Chern classes \(k=md\) divisible by d. Shifting m by the integer r/d simplifies this to
To sum this we write
By the results of Göttsche–Soergel [GS], it is the unique Jacobi cusp form of index 10 and weight 1,
It specialises at \(t=1\) to the modular form \(\eta (q)^{24}\).
Taking only powers \(k=\frac{r}{d}m\) of q divisible by the integer r/d on both sides of this formula, and substituting \(t^d\) for t, gives
Substituting in (5.45) gives
Conjecture 5.47
If \({\mathcal {O}}_S(1)\) is generic then
where \({\widetilde{\Delta }}\) is given by (5.46).
Again, when r is prime, this was already conjectured by Göttsche–Kool [GK3], and is proved by Theorem 5.44.
Theorem 5.48
If \({\mathcal {O}}_S(1)\) is generic and r is prime then
\(\square \)
5.5 \({\mathbf {K}}_{\mathbf {S}}>{\mathbf {0}}\)
Finally we describe the refinement of a simple calculation on general type surfaces S from [TT2, Section 6.3]. For more recent and much more general results we refer to the discussion of Laarakker’s results [La2] in the Introduction.
Take a surface S with \(h^{0,1}(S)=0\) and \(h^{0,2}(S)>0\) and charge \(\alpha =(2,0,0)\in H^*(S)\). The \({\mathbb {C}}^*\)-fixed semistable sheaves on \(X=K_S\) are
-
(a)
(the pushforward from S of) \({\mathcal {O}}_S^{\oplus 2}\), and
-
(b)
(the pushforward from \(2S\subset X\) of) \(I_{C\subset 2S}\otimes K_S\), for any \(C\subset S\subset 2S\subset X\) in the canonical linear system \(|K_S|\).
Taking sections twisted by \({\mathcal {O}}(n)\) for \(n\gg 0\) (using in (b) the fact that the pushdown to S of \(I_{C\subset 2S}\otimes K_S\) is \({\mathcal {O}}_S\oplus {\mathcal {O}}_S{\mathfrak {t}}^{-1}\)), imposing stability and dividing by the automorphism group of the sheaf, we find the following. The moduli space of \({\mathbb {C}}^*\)-fixed stable Joyce–Song pairs has two components,
-
(a)
\({\text {Gr}}(2,\Gamma ({\mathcal {O}}_S(n)))\) of pairs with underlying sheaf \({\mathcal {O}}_S^{\oplus 2}\), and
-
(b)
\({\mathbb {P}}(\Gamma ({\mathcal {O}}_S(n)))\times {\mathbb {P}}(\Gamma (K_S))\) of pairs with underlying sheaf \(I_{C\subset 2S}K_S\).
The first component has a trivial \(H^2({\mathcal {O}}_S)\) piece in the obstruction bundle , so it contributes nothing to the invariants. The second component is shown in [TT2, Section 6.3] to have fixed obstruction bundle
pulled back from \({\mathbb {P}}(\Gamma (K_S))\), and virtual normal bundle
A generic element of \({\text {End}}_0\Gamma (K_S)\cong H^0(T_{{\mathbb {P}}(\Gamma (K_S))})\) with distinct eigenvalues gives a vector field on \({\mathbb {P}}(\Gamma (K_S))\) with \(p_g(S)\) distinct zeros, and so a vector field on \({\mathbb {P}}(\Gamma ({\mathcal {O}}_S(n)))\times {\mathbb {P}}(\Gamma (K_S))\) whose zero locus is \(p_g(S)\) distinct \({\mathbb {P}}(\Gamma ({\mathcal {O}}_S(n)))\) fibres. By (5.49) the corresponding Koszul resolution gives an equality in K-theory
so that the refined pairs invariant is
On a \({\mathbb {P}}(\Gamma ({\mathcal {O}}_S(n)))\) fibre the virtual normal bundle (5.50) simplifies to
where \(\Psi :=T_{{\mathbb {P}}(\Gamma ({\mathcal {O}}_S(n)))}{\mathfrak {t}}^{-1}\). Combined with (5.49) this means \(K_{{\text {vir}}}\) is
with square root
So we now calculate (5.51) to be
By two applications of the identity (2.28) (and recalling that \({\text {rank}}\Psi =\chi ({\mathcal {O}}_S(n))-1\)) this gives
Since \([\chi ]^{}_{t^2}=[2\chi ]^{}_t/[2]^{}_t\) this gives
This fits Conjecture (5.2) perfectly and makes the refined Vafa–Witten invariant
Notes
Mathematicians should consider their calculations as conjectures we cannot yet prove.
tmf is a deep theory over the integers [Ho]; we only use its rational version which is trivial to define using the Witten genus and the Landweber exact functor theorem.
Here \(\alpha \) is the total Chern class of the sheaves on S underlying the Vafa–Witten Higgs pairs in our moduli space.
There is a refinement of DT theory based on the two-variable Hodge–Deligne polynomial E(u, v). Here we use the one-variable specialisation based on the Hirzebruch \(\chi ^{}_{-t}:=E(t,1)\) genus; see Sect. 5.1 for details and definitions.
I did the calculations repeatedly until they converged; only then did I allow Martijn Kool to tell me his prediction from [GK3]; fortunately the results matched.
For instance, this symmetrisation will lead, via Serre duality, to the \(t^{1/2}\leftrightarrow t^{-1/2}\) symmetry of Proposition 2.27.
We are abusing the notation \(\ \cdot \ |_{M^T}\) since we have not shown this line bundle extends to M. The point is we will only need it on \(M^T\). And our square root is only equivariant for the action of the double cover of T, since we need to use \({\mathfrak {t}}^{1/2}\).
In fact it would be sufficient to invert \(t^i-1\) for all \(i=1,2,3,\ldots \,\).
When \(p_g(S)>0\) it is shown in [GT1, Section 6] how to remove \(H^2({\mathcal {O}}_S)\) from the complex to give the same result.
It is shown in [GT1, Section 10] that the two perfect obstruction theories \(E^{\bullet }\rightarrow {\mathbb {L}}_{S^{[n_1,n_2]}}\) have isomorphic virtual cotangent bundles \(E^{\bullet }\), but not that their maps to the cotangent complex \({\mathbb {L}}\) are the same (though they surely are).
The general case is handled in [TT2].
But we do use that \(l_i^3=0=m_i^3\).
If the universal sheaf is twisted by a nonzero Brauer class then is not the projectivisation of an untwisted bundle, so the hyperplane class does not lift to \(H^2({\mathcal {P}}^\perp _{\alpha ,n})\). But its fibrewise class in \(H^0({\mathcal {N}}^\perp _{\alpha ,n},R^1p_*\,\Omega _p)\) is well-defined and is all we use.
Since the existence of orientation data compatible with the Hall algebra product is still an open problem in general, the development of refined DT theory has stalled. In our situation all our moduli stacks are \((-1)\)-shifted cotangent bundles of smooth stacks, which makes things much simpler.
There is a further refinement given by taking the two variable Hodge–Deligne polynomial E(u, v) of the stack \(\epsilon _\alpha \). Here we take its specialisation \(\chi ^{}_{-t}=E(t,1)\).
We have used the genericity of \({\mathcal {O}}_S(1)\) to simplify the sum to one over only charges proportional to \(\alpha \).
Hence we get only one of the two cosections of [PT, Equation 5.8]. This is sufficient since the Vafa–Witten \(R{\text {Hom}}(I^{\bullet },I^{\bullet })^{}_\perp [1]\) obstruction theory of [TT1, TT2] has already had an \(H^2({\mathcal {O}}_S)\) term removed from the obstruction sheaf, i.e. it is a reduced obstruction theory in the language of [PT].
This flow is most easily understood in terms of sheaves on X [PT, Section 5]; for instance it takes the sheaf \({\mathcal {O}}_{rS}\) at \(t=0\) to \({\mathcal {O}}_{(r-1)\Gamma _{-t\sigma /r}}\oplus {\mathcal {O}}_{\Gamma _{t\sigma }}\) at time \(t\ne 0\), where \(\Gamma _\sigma \subset K_S\) is the graph of \(\sigma \).
That is, they have torsion cokernel.
References
Anderson, D.: \(K\)-theoretic Chern class formulas for vexillary degeneracy loci. Adv. Math. 350, 440–485 (2019). arXiv:1701.00126
Behrend, K.: Donaldson–Thomas invariants via microlocal geometry. Ann. Math. 170, 1307–1338 (2009). arXiv:math.AG/0507523
Behrend, K., Fantechi, B.: The intrinsic normal cone. Invent. Math. 128, 45–88 (1997). arXiv:alg-geom/9601010
Carlsson, E., Nekrasov, N., Okounkov, A.: Five dimensional gauge theories and vertex operators. Mosc. Math. J. 14, 9–61 (2014). arXiv:1308.2465
Carlsson, E., Okounkov, A.: Exts and vertex operators. Duke Math J. 161, 1797–1815 (2012). arXiv:0801.2565
Ciocan-Fontanine, I., Kapranov, M.: Virtual fundamental classes via dg-manifolds. Geom. Top. 13, 1779–1804 (2009). arXiv:mathAG/0703214
Davison, B., Meinhardt, S.: Donaldson–Thomas theory for categories of homological dimension one with potential. arXiv:1512.08898
Dijkgraaf, R., Park, J.-S., Schroers, B.: \(N=4\) supersymmetric Yang–Mills theory on a Kähler surface. arXiv:hep-th/9801066
Ellingsrud, G., Göttsche, L., Lehn, M.: On the cobordism class of the Hilbert scheme of a surface. J. Algebraic Geom. 10, 81–100 (2001). arXiv:mathAG/9904095
Fantechi, B., Göttsche, L.: Riemann–Roch theorems and elliptic genus for virtually smooth schemes. Geom. Top. 14, 83–115 (2010). arXiv:0706.0988
Gholampour, A., Sheshmani, A., Yau, S.-T.: Nested Hilbert schemes on surfaces: Virtual fundamental class. Adv. Math. 365, 107046 (2020). arXiv:1701.08899
Gholampour, A., Sheshmani, A., Yau, S.-T.: Localized Donaldson-Thomas theory of surfaces. Am. J. Math. 142, 405–442 (2020). arXiv:1701.08902
Gholampour, A., Thomas, R.P.: Degeneracy loci, virtual cycles and nested Hilbert schemes I. Tunis. J. Math. 2, 633–665 (2019). arXiv:1709.06105
Gholampour, A., Thomas, R. P.: Degeneracy loci, virtual cycles and nested Hilbert schemes II. to appear in Compositio (2020). arXiv:1902.04128
Göttsche, L., Kool, M.: Virtual refinements of the Vafa-Witten formula. Commun. Math. Phys. 376, 1–49 (2020). arXiv:1703.07196
Göttsche, L., Kool, M.: A rank 2 Dijkgraaf–Moore–Verlinde–Verlinde formula. Commun. Number Theory Phys. 13, 165–201 (2019). arXiv:1801.01878
Göttsche, L., Kool, M.: Refined \(SU(3)\) Vafa–Witten invariants. arXiv:1808.03245
Göttsche, L., Soergel, W.: Perverse sheaves and the cohomology of Hilbert schemes of smooth algebraic surfaces. Math. Ann. 296, 235–245 (1993)
Graber, T., Pandharipande, R.: Localization of virtual classes. Invent. Math. 135, 487–518 (1999). arXiv:alg-geom/9708001
Hopkins, M.: Topological modular forms, the Witten genus, and the theorem of the cube. Proc. ICM Zürich, Birkhäuser, pp. 554–565 (1995)
Hudson, T., Ikeda, T., Matsumura, T., Naruse, H.: Degeneracy loci classes in \(K\)-theory—determinantal and Pfaffian formula. Adv. Math. 320, 115–156 (2017). arXiv:1504.02828
Jiang, Y., Thomas, R.P.: Virtual signed Euler characteristics. J. Algebraic Geom. 26, 379–397 (2017). arXiv:1408.2541
Joyce, D.: Configurations in abelian categories. II. Ringel–Hall algebras. Adv. Math. 210, 635–706 (2007). arXiv:math.AG/0503029
Joyce, D.: Configurations in abelian categories. III. Stability conditions and identities. Adv. Math. 215, 153–219 (2007). arXiv:math.AG/0410267
Joyce, D., Song, Y.: A theory of generalized Donaldson–Thomas invariants. Memoirs of the AMS, vol. 217(1020) (2012). arXiv:0810.5645
Kiem, Y., Li, J.: Localizing virtual structure sheaves by cosections. IMRN rny235 (2018). arXiv:1705.09458
Kool, M., Thomas, R.P.: Reduced classes and curve counting on surfaces I: theory. Algebraic Geom. 1, 334–383 (2014). arXiv:1112.3069
Laarakker, T.: Monopole contributions to refined Vafa-Witten invariants. to appear in Geom. Top. (2020). arXiv:1810.00385
Laarakker, T.: Vertical Vafa-Witten invariants. arXiv:1906.01264
Li, J., Tian, G.: Virtual moduli cycles and Gromov–Witten invariants of algebraic varieties. J. Am. Math. Soc. 11, 119–174 (1998). arXiv:alg-geom/9602007
Maulik, D.: in preparation
Maulik, D., Okounkov, A.: Nested Hilbert schemes and symmetric functions (unpublished)
Maulik, D., Thomas, R.P.: Sheaf counting on local K3 surfaces. Pure Appl. Math. Q. 14, 419–441 (2018). arXiv:1806.02657
Maulik, D., Thomas, R.P.: in preparation
Nekrasov, N., Okounkov, A.: Membranes and sheaves. Algebraic Geom. 3, 320–369 (2016). arXiv:1404.2323
Pandharipande, R., Thomas, R.P.: The Katz–Klemm–Vafa conjecture for K3 surfaces. For. Math. Pi 4, 1–111 (2016). arXiv:1404.6698
Qu, F.: Virtual pullbacks in \(K\)-theory. Ann. Inst. Fourier 68, 1609–1641 (2018). arXiv:1608.02524
Schiffmann, O., Vasserot, E.: The elliptic Hall algebra and the equivariant \(K\)-theory of the Hilbert scheme of \({\mathbb{A}}^2\). arXiv:0905.2555
Shen, J.: Cobordism invariants of the moduli space of stable pairs. J. LMS 94, 427–446 (2016). arXiv:1409.4576
Tanaka, Y., Thomas, R.P.: Vafa–Witten invariants for projective surfaces I: stable case. to appear in J. Algebraic Geom. arXiv:1702.08487
Tanaka, Y., Thomas, R.P.: Vafa–Witten invariants for projective surfaces II: semistable case. Pure Appl. Math. Q. 13, 517–562 (2017). Volume in honour of the 60th birthday of Simon Donaldson. arXiv:1702.08488
Thomas, R.P.: A \(K\)-theoretic Fulton class. arXiv:1810.00079
Toda, Y.: Stable pairs on local K3 surfaces. J. Differ. Geom. 92, 285–370 (2012). arXiv:1103.4230
Vafa, C., Witten, E.: A strong coupling test of S-duality. Nucl. Phys. B 432, 484–550 (1994). arXiv:hep-th/9408074
Acknowledgements
This paper originally grew out of a suggestion of Davesh Maulik, and is part of the joint work [MT2]. Ideas, suggestions and calculations of Martijn Kool played a crucial role in the formulation of both [MT2, TT1] and this paper, as did the insistence of Emanuel Diaconescu, Greg Moore and Edward Witten that there should be a refinement of the Vafa–Witten invariants defined in [TT1, TT2]. Thanks to Ties Laarakker for suggesting the vanishing of Sects. 5.2 and 5.3, and for correcting an error in [TT2] which had propagated into this paper. I am grateful to Noah Arbesfeld, Pierrick Bousseau and Andrei Negut for sharing their expertise in K-theory and the Nekrasov-Okounkov refinement, and to Dominic Joyce and Sven Meinhardt for their help with refined DT theory. The author is partially supported by EPSRC Grant EP/R013349/1.
Author information
Authors and Affiliations
Corresponding author
Additional information
Communicated by H. T. Yau
Publisher's Note
Springer Nature remains neutral with regard to jurisdictional claims in published maps and institutional affiliations.
Rights and permissions
Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http://creativecommons.org/licenses/by/4.0/.
About this article
Cite this article
Thomas, R.P. Equivariant K-Theory and Refined Vafa–Witten Invariants. Commun. Math. Phys. 378, 1451–1500 (2020). https://doi.org/10.1007/s00220-020-03821-1
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1007/s00220-020-03821-1