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Why Noether’s theorem applies to statistical mechanics

Sophie Hermann, Matthias Schmidt

2022Journal of Physics Condensed Matter31 citationsDOIOpen Access PDF

Abstract

Abstract Noether’s theorem is familiar to most physicists due its fundamental role in linking the existence of conservation laws to the underlying symmetries of a physical system. Typically the systems are described in the particle-based context of classical mechanics or on the basis of field theory. We have recently shown (2021 Commun. Phys. 4 176) that Noether’s reasoning also applies to thermal systems, where fluctuations are paramount and one aims for a statistical mechanical description. Here we give a pedagogical introduction based on the canonical ensemble and apply it explicitly to ideal sedimentation. The relevant mathematical objects, such as the free energy, are viewed as functionals. This vantage point allows for systematic functional differentiation and the resulting identities express properties of both macroscopic average forces and molecularly resolved correlations in many-body systems, both in and out-of-equilibrium, and for active Brownian particles. To provide further background, we briefly describe the variational principles of classical density functional theory, of power functional theory, and of classical mechanics.

Topics & Concepts

Statistical mechanicsContext (archaeology)Statistical physicsIdeal (ethics)Homogeneous spaceAnalytical mechanicsBrownian motionMathematicsField (mathematics)Classical mechanicsPoint (geometry)Theoretical physicsConservation lawPhysicsBasis (linear algebra)Statistical ensembleClassical physicsCalculus (dental)Brownian dynamicsMathematical structurePhysical systemThermal fluctuationsMathematical theoryAdvanced Thermodynamics and Statistical MechanicsElectrostatics and Colloid InteractionsAdvanced Physical and Chemical Molecular Interactions