Noether Symmetries and Covariant Conservation Laws in Classical, Relativistic and Quantum Physics

TL;DR

This paper reviews Noether symmetries and covariant conservation laws across classical, relativistic, and quantum physics, emphasizing geometric formulations and recent applications in various field theories.

Contribution

It introduces a unified geometric framework for Noether symmetries and conservation laws, including new applications in classical mechanics, gravity, and quantum field theories.

Findings

Defined strong conservation laws in a frame-independent way

Analyzed energy and entropy in various formulations of General Relativity

Applied conservation laws to Loop Quantum Gravity using spin connections

Abstract

We review the Lagrangian formulation of Noether symmetries (as well as "generalized Noether symmetries") in the framework of Calculus of Variations in Jet Bundles, with a special attention to so-called "Natural Theories" and "Gauge-Natural Theories", that include all relevant Field Theories and physical applications (from Mechanics to General Relativity, to Gauge Theories, Supersymmetric Theories, Spinors and so on). It is discussed how the use of Poincare'-Cartan forms and decompositions of natural (or gauge-natural) variational operators give rise to notions such as "generators of Noether symmetries", energy and reduced energy flow, Bianchi identities, weak and strong conservation laws, covariant conservation laws, Hamiltonian-like conservation laws (such as, e.g., so-called ADM laws in General Relativity) with emphasis on the physical interpretation of the quantities calculated in specific cases (energy, angular momentum, entropy, etc.). A few substantially new and very recent applications/examples are presented to better show the power of the methods introduced: one in Classical Mechanics (definition of strong conservation laws in a frame-independent setting and a discussion on the way in which conserved quantities depend on the choice of an observer); one in Classical Field Theories (energy and entropy in General Relativity, in its standard formulation, in its spin-frame formulation, in its first order formulation "`a la Palatini" and in its extensions to Non-Linear Gravity Theories); one in Quantum Field Theories (applications to conservation laws in Loop Quantum Gravity via spin connections and Barbero-Immirzi connections).