Quantum Riemann - Roch, Lefschetz and Serre
Abstract
Given a holomorphic vector bundle over a compact K\"ahler manifold, one introduces twisted GW-invariants of replacing virtual fundamental cycles of moduli spaces of stable maps by their cap-product with a chosen multiplicative characteristic class of . Using the formalism of quantized quadratic hamiltonians, we express the descendent potential for the twisted theory in terms of that for . The result (Theorem 1) is a consequence of Mumford's Riemann -- Roch -- Grothendieck formula applied to the universal stable map. When is concave, and the inverse -equivariant Euler class is chosen, the twisted theory yields GW-invariants of . The ``non-linear Serre duality principle'' expresses GW-invariants of via those of the supermanifold , where the Euler class and replace the inverse Euler class and . We derive from Theorem 1 the nonlinear Serre duality in a very general form (Corollary 2). When the bundle is convex, and a submanifold is defined by a global section, the genus 0 GW-invariants of coincide with those of . We prove a ``quantum Lefschetz hyperplane section principle'' (Theorem 2) expressing genus 0 GW-invariants of a complete intersection via those of . This extends earlier results of Y.-P. Lee and A. Gathmann and yields most of the known mirror formulas for toric complete intersections.
Cite
@article{arxiv.math/0110142,
title = {Quantum Riemann - Roch, Lefschetz and Serre},
author = {Tom Coates and Alexander Givental},
journal= {arXiv preprint arXiv:math/0110142},
year = {2007}
}
Comments
26 pages; in this version, we correct several errors in Appendix 2