Non-Perturbative Aspects of Quantum Electrodynamics on Curved Space and Investigations in Matrix Gravity

TL;DR

This dissertation explores non-perturbative quantum electrodynamics effects on curved space using heat kernel techniques and investigates novel aspects of Matrix Gravity, including its equations and particle dynamics.

Contribution

It introduces a new non-perturbative heat kernel expansion and applies it to quantum electrodynamics, and develops the theory and corrections of Matrix Gravity.

Findings

Derived a generalized Schwinger effect with gravitational corrections.

Discovered new infrared divergences due to gravity.

Computed non-commutative corrections to Einstein equations.

Abstract

In the first part of this Dissertation, we study non-perturbative aspects of quantum electrodynamics on Riemannian manifolds by using heat kernel asymptotic expansion techniques. Here, we established the existence of a new non-perturbative heat kernel asymptotic expansion for a Laplace type operator on homogeneous Abelian bundles with parallel curvature, and we evaluated explicitly the first three coefficients. As an application, we computed the imaginary part of the non-perturbative effective action in quantum electrodynamics and derived a generalization of the classical Schwinger's result for the creation of scalar and spinor particles in an electromagnetic field induced by the gravitational field. We also discovered new infrared divergences due to the gravitational corrections, which represents a completely new physical effect. In the second part of the Dissertation, we studied some aspects of a newly developed non-commutative theory of the gravitational field called Matrix Gravity. There are two versions of Matrix Gravity, in the first one, called Matrix General Relativity, the action functional is obtained by generalizing the Hilbert-Einstein functional to matrix-valued quantities. In the second one, called Spectral Matrix Gravity, the action is constructed form the first two spectral invariants of a non-Laplace type second order partial differential operator. For the first version, we found the dynamical equations of the theory, while, for the second version, we computed the first non-commutative corrections to Einstein equations in the weak deformation limit. Furthermore, we developed the kinematics of test particles in Matrix Gravity and found the first and second order corrections to the usual Riemannian geodesic flow.