In mathematics, specifically algebraic geometry, Donaldson–Thomas theory is the theory of Donaldson–Thomas invariants. Given a compact moduli space of sheaves on a Calabi–Yau threefold, its Donaldson–Thomas invariant is the virtual number of its points, i.e., the integral of the cohomology class 1 against the virtual fundamental class. The Donaldson–Thomas invariant is a holomorphic analogue of the Casson invariant. The invariants were introduced by . Donaldson–Thomas invariants have close connections to Gromov–Witten invariants of algebraic three-folds and the theory of stable pairs due to Rahul Pandharipande and Thomas.
Donaldson–Thomas theory is physically motivated by certain BPS states that occur in string and gauge theory[1] pg 5. This is due to the fact the invariants depend on a stability condition on the derived category
Db(l{M})
l{P}\subsetDb(l{M})
The basic idea of Gromov–Witten invariants is to probe the geometry of a space by studying pseudoholomorphic maps from Riemann surfaces to a smooth target. The moduli stack of all such maps admits a virtual fundamental class, and intersection theory on this stack yields numerical invariants that can often contain enumerative information. In similar spirit, the approach of Donaldson–Thomas theory is to study curves in an algebraic three-fold by their equations. More accurately, by studying ideal sheaves on a space. This moduli space also admits a virtual fundamental class and yields certain numerical invariants that are enumerative.
Whereas in Gromov–Witten theory, maps are allowed to be multiple covers and collapsed components of the domain curve, Donaldson–Thomas theory allows for nilpotent information contained in the sheaves, however, these are integer valued invariants. There are deep conjectures due to Davesh Maulik, Andrei Okounkov, Nikita Nekrasov and Rahul Pandharipande, proved in increasing generality, that Gromov–Witten and Donaldson–Thomas theories of algebraic three-folds are actually equivalent.[2] More concretely, their generating functions are equal after an appropriate change of variables. For Calabi–Yau threefolds, the Donaldson–Thomas invariants can be formulated as weighted Euler characteristic on the moduli space. There have also been recent connections between these invariants, the motivic Hall algebra, and the ring of functions on the quantum torus.
For a Calabi-Yau threefold
Y
\alpha\inHeven(Y,Q)
l{M}(Y,\alpha)
c(l{E})=\alpha
l{M}\sigma(Y,\alpha)
l{E}
\sigma
\sigma
Now because\begin{align} T[l{E]}l{M}\sigma(Y,\alpha)&\cong
1(l{E},l{E})\\ Ob Ext [l{E ]}(l{M}\sigma(Y,\alpha))&\congExt2(l{E},l{E}) \end{align}
Y
which gives a perfect obstruction theory of dimension 0. In particular, this implies the associated virtual fundamental classExt2(l{E},l{E})\congExt
\vee Y) \congExt1(l{E},l{E})\vee
is in homological degree[l{M}\sigma(Y,\alpha)]vir\in
\sigma(Y,\alpha), H 0(l{M} Z)
0
which depends upon the stability condition}1
\sigma(Y,\alpha)] \int [l{M vir
\sigma
\alpha
Yt