Quantization of Kähler manifolds via differential operators

Abstract

In this paper, we study the quantization of classical observables (i.e., functions) on a Kähler manifold X as differential operators acting on holomorphic sections of tensor powers L k of the pre-quantum line bundle L. We prove two global results as follows. (1). For a general smooth function f ∈ C∞(X), we construct higher order generalizations of Kostant-Souriau's pre-quantum differential operators using our Fedosov-type constructions of Bargmann-Fock sheaves in previous works. We prove that these differential operators are asymptotic to the Berezin-Toeplitz operators Tf,k acting on the Hilbert space H0(X, L k) as k ∞. (2). If a smooth function f ∈ C∞(X) is furthermore the symbol of a level k quantizable function , then we prove that the associated Berezin-Toeplitz operator Tf,k is a holomorphic differential operator. Conversely, Berezin-Toeplitz operators that are holomorphic differential operators all arise in this way. This gives a complete characterization of when Berezin-Toeplitz operators are holomorphic differential operators. To prove these results, we establish new orthogonality relations which generalize the classical Tuynman's Lemma, and employ various differential-geometric and analytic technqiues such as Hörmander's estimates.