On Newton's Third Law and its Symmetry-Breaking Effects

TL;DR

This paper investigates the fundamental Newton's third law, revealing that it may not hold in out-of-equilibrium systems due to entropic effects, and explores the role of the physical vacuum in this context.

Contribution

It introduces a new statistical mechanics approach showing violations of Newton's third law in non-equilibrium systems and highlights the physical vacuum's role in these effects.

Findings

Newton's third law is violated out of equilibrium due to entropic gradients.

The physical vacuum can explain potential violations of action-reaction.

A new entropy-maximizing framework for momentum in statistical mechanics.

Abstract

The law of action-reaction, considered by Ernst Mach the cornerstone of physics, is thoroughly used to derive the conservation laws of linear and angular momentum. However, the conflict between momentum conservation law and Newton's third law, on experimental and theoretical grounds, call for more attention. We give a background survey of several questions raised by the action-reaction law and, in particular, the role of the physical vacuum is shown to provide an appropriate framework to clarify the occurrence of possible violations of the action-reaction law. Then, in the framework of statistical mechanics, using a maximizing entropy procedure, we obtain an expression for the general linear momentum of a body-particle. The new approach presented here shows that Newton's third law is not verified in systems out of equilibrium due to an additional entropic gradient term present in the particle's momentum.