N=1 Geometric Supergravity and chiral triples on Riemann surfaces

Abstract

We construct a global geometric model for the bosonic sector and Killing spinor equations of four-dimensional N=1 supergravity coupled to a chiral non-linear sigma model and a Spinc0 structure. The model involves a Lorentzian metric g on a four-manifold M, a complex chiral spinor and a map M M from M to a complex manifold M endowed with a novel geometric structure which we call chiral triple. Using this geometric model, we show that if M is spin the K\"ahler-Hodge condition on a complex manifold M is enough to guarantee the existence of an associated N=1 chiral geometric supergravity, positively answering a conjecture proposed by D. Z. Freedman and A. V. Proeyen. We dimensionally reduce the Killing spinor equations to a Riemann surface X, obtaining a novel system of partial differential equations for a harmonic map with potential X M from X into the K\"ahler moduli space M of the theory. We characterize all Riemann surfaces admitting supersymmetric solutions with vanishing superpotential, proving that they consist on holomorphic maps of Riemann surfaces into M satisfying certain compatibility condition with respect to the canonical bundle of X and the chiral triple of the theory. Furthermore, we classify the biholomorphism type of all Riemann surfaces carrying supersymmetric solutions with complete Riemannian metric and finite-energy scalar map.