Geometrically Induced Gauge Structure on Manifolds Embedded in a Higher Dimensional Space

TL;DR

This paper explores how the geometry of a curved manifold embedded in higher-dimensional space induces a gauge structure, linking geometric properties to gauge potentials and applying the formalism to field theories with soliton solutions.

Contribution

It introduces a formalism for describing gauge structures induced by embedding geometry, extending to infinite-dimensional cases and connecting to soliton field theories.

Findings

Derived the gauge structure from the embedding geometry.

Connected the gauge potential to Berry's phase via Gauss mapping.

Extended the formalism to infinite-dimensional field theories.

Abstract

We explain in a context different from that of Maraner the formalism for describing motion of a particle, under the influence of a confining potential, in a neighbourhood of an n-dimensional curved manifold M^n embedded in a p-dimensional Euclidean space R^p with p >= n+2. The effective Hamiltonian on M^n has a (generally non-Abelian) gauge structure determined by geometry of M^n. Such a gauge term is defined in terms of the vectors normal to M^n, and its connection is called the N-connection. In order to see the global effect of this type of connections, the case of M^1 embedded in R^3 is examined, where the relation of an integral of the gauge potential of the N-connection (i.e., the torsion) along a path in M^1 to the Berry's phase is given through Gauss mapping of the vector tangent to M^1. Through the same mapping in the case of M^1 embedded in R^p, where the normal and the tangent quantities are exchanged, the relation of the N-connection to the induced gauge potential on the (p-1)-dimensional sphere S^{p-1} (p >= 3) found by Ohnuki and Kitakado is concretely established. Further, this latter which has the monopole-like structure is also proved to be gauge-equivalent to the spin-connection of S^{p-1}. Finally, by extending formally the fundamental equations for M^n to infinite dimensional case, the present formalism is applied to the field theory that admits a soliton solution. The resultant expression is in some respects different from that of Gervais and Jevicki.