A conformal gauge theory of solids: insights into a class of electromechanical and magnetomechanical phenomena
Pranesh Roy, J N Reddy, Debasish Roy

TL;DR
This paper develops a gauge theory of solids with conformal symmetry to model electromechanical and magnetomechanical phenomena, revealing deep geometric connections and providing analytical solutions for piezoelectricity.
Contribution
It introduces a novel gauge-theoretic framework for modeling coupled electromechanical and magnetomechanical effects in solids, linking geometry with physical phenomena.
Findings
Modeling of flexoelectricity as a gauge theory with conformal symmetry
Representation of magnetomechanical effects via Hodge decomposition
Analytical solution illustrating the approach's insights
Abstract
A gauge theory of solids with conformal symmetry is formulated to model various electromechanical and magnetomechanical coupling phenomena. If the pulled back metric of the current configuration (the right Cauchy-Green tensor) is scaled with a constant, the volumetric part of the Lagrange density changes while the isochoric part remains invariant. However, upon a position dependent scaling, the isochoric part also loses invariance. In order to restore the invariance of the isochoric part, a 1-form compensating field is introduced and the notion of a gauge covariant derivative is utilized to minimally replace the Lagrangian. In view of obvious similarities with the Weyl geometry, the Weyl condition is imposed through the Lagrangian and a minimal coupling is employed so the 1-form could evolve. On deriving the Euler-Lagrange equations based on the action functional, we observe a close…
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