Superradiance: Classical, Relativistic and Quantum Aspects

TL;DR

This paper provides a comprehensive analysis of superradiance across classical, relativistic, and quantum domains, exploring its theoretical foundations, specific systems like black holes, and quantum effects, highlighting its significance in current physics research.

Contribution

It offers a unified framework for understanding superradiance, including criteria for its occurrence, explicit calculations for black holes, and quantum aspects linking superradiance to thermodynamics and spin-statistics.

Findings

Superradiance occurs when the reflection coefficient exceeds unity.

Explicit formulas for superradiance in spinning black holes are derived.

Quantum effects and thermodynamic relations of superradiance are analyzed.

Abstract

Several physical systems can be treated as a scattering process, and, for these processes, a natural observed quantity arises: the ratio between the reflected and incident intensities, known as the reflection coefficient. This dissertation is concerned with the phenomenon known as superradiance, that is, when this coefficient is larger than unity. We shall explore many examples of such systems, and, more importantly, we shall also see how, apart from the interest in its own right, superradiance is related to a number of important current research physical issues. We begin with a small survey of important results on chapter one. On chapter two, we establish a general criteria to decide whether or not superradiant scattering is observed based on the linear, second order, homogeneous ordinary differential equation (ODE) or linear, first order homogeneous systems of ODEs which describes the process and we shall give an example of system in which superradiance is observed. On chapter three, we focus on spinning black hole superradiance, we shall describe how one can compute explicitly the reflection coefficient for different spin waves. Chapter four is dedicated to the relations with thermodynamics. We develop what is meant by black hole thermodynamics, particularly the so-called first and second law of black hole thermodynamics, and apply them in the context of superradiance, so we can generalise some of the results from chapter three to more general black holes. Finally, on chapter five, we explore many of the quantum aspects of superradiance, including the relation with the Klein paradox, and the quantum version of black hole superradiance, for the later we will explain briefly how one usually quantise fields in curved space-time. A further connection with thermodynamics is explored. Thorough all this text we analyse the connection between superradiance and spin and statistics.