Advances in the Worldline Approach to Quantum Field Theory: Strong Fields, Amplitudes and Gravity

TL;DR

This thesis explores the first-quantized worldline formalism in quantum field theory, demonstrating its versatility and efficiency in analyzing strong fields, scattering amplitudes, and gravity across various particle spins.

Contribution

It advances the worldline approach to complex physical situations, including strong background fields and higher-spin particles, showcasing its computational power and broad applicability.

Findings

Efficient computation of scattering amplitudes.

Systematic perturbative expansions of the heat kernel.

Extension of the worldline formalism to spin-2 particles.

Abstract

This thesis is devoted to the first-quantized approach to quantum field theory, commonly known as the 'Worldline Formalism'. It collects most of the works completed by the author during the PhD, illustrating the versatility and efficiency of this formalism across a broad range of physical contexts. The applications discussed fall into two broad categories: perturbative and non-perturbative analyses. In particular, the thesis investigates how quantum particles interact with strong background fields, how scattering amplitudes can be efficiently computed, and how perturbative expansions of the heat kernel can be systematically performed. These studies highlight recent advances in extending the worldline approach to increasingly complex situations. Different field theories are examined from this first-quantized perspective and are organized according to the spin of the particle under consideration. The discussion begins with the seemingly simple scalar case, progresses through spin 1, both in the abelian and the non-abelian case, and concludes with spin-2 particles, both in the massless and in the massive realizations. Through this sequence of examples, the thesis aims to demonstrate the flexibility as well as the computational power of the Worldline Formalism in addressing fundamental open problems in theoretical physics.