Geometric Nonlinearities in Field Theory, Condensed Matter and Analytical Mechanics

TL;DR

This paper explores the deep connection between fundamental nonlinearities and large symmetry groups across various physics domains, highlighting the importance of non-perturbative effects and high symmetries in understanding physical models.

Contribution

It proposes a conceptual link between essential nonlinearities and dynamical symmetries, especially large symmetry groups, in field theory, condensed matter, and analytical mechanics.

Findings

Nonlinearity is fundamental and often linked to large symmetry groups.

Symmetries in soliton theory relate to integrals of motion and infinite-dimensional groups.

The paper discusses the connection in familiar physical problems, not just soliton models.

Abstract

There are two very important subjects in physics: Symmetry of dynamical models and nonlinearity. All really fundamental models are invariant under some particular symmetry groups. There is also no true physics, no our Universe and life at all, without nonlinearity. Particularly interesting are essential, non-perturbative nonlinearities which are not described by correction terms imposed on some well-defined linear background. Our idea in this paper is that there exists some mysterious, not yet understood link between essential, physically relevant nonlinearity and dynamical symmetry, first of all, large symmetry groups. In some sense the problem is known even in soliton theory, where the essential nonlinearity is often accompanied by the infinite system of integrals of motion, thus, by infinite-dimensional symmetry groups. Here we discuss some more familiar problems from the realm of field theory, condensed matter physics, and analytical mechanics, where the link between essential nonlinearity and high symmetry is obvious, even if not yet fully understood.