Fermionic Dyson expansions and stochastic Duistermaat-Heckman localization on loop spaces
Abstract
Given a self-adjoint operator H≥ 0 and (appropriate) densely defined and closed operators P1,…, Pn in a Hilbert space H, we provide a systematic study of bounded operators given by iterated integrals alignoh ∫\ 0≤ s1≤ …≤ sn≤ t\e-s1HP1e-(s2-s1)HP2·s e-(sn-sn-1)HPn e-(t-sn)H\, d s1 … d sn, t>0. align These operators arise naturally in noncommutative geometry and the geometry of loop spaces. Using Fermionic calculus, we give a natural construction of an enlarged Hilbert space H(n) and an analytic semigroup e-t (H(n)+P(n) ) thereon, such that e-t (H(n)+P(n) ) composed from the left with (essentially) a Fermionic integration gives precisely the above iterated operator integral. This formula allows to establish important regularity results for the latter, and to derive a stochastic representation for it, in case H is a covariant Laplacian and the Pj's are first-order differential operators. Finally, with H given as the square of the Dirac operator on a spin manifold, this representation is used to derive a stochastic refinement of the Duistermaat-Heckman localization formula on the loop space of a spin manifold.
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