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Supersymmetry and Nonreciprocity

Savdeep Sethi, Gabriel Artur Weiderpass

Abstract

Nonreciprocal theories are used to model a broad array of non-equilibrium phenomena found in nature ranging from biological systems like networks of neurons to the behavior of overflowing water fountains. This includes systems broadly classified as active matter systems. We show that the stochastic theories which describe nonreciprocal interactions can be mapped into quantum field theories described by a supersymmetric action with a single supercharge. The theories are generically non-Hermitian. This generalizes the past work of Parisi and Sourlas on reciprocal theories, which model systems with interactions derived from potentials.

Supersymmetry and Nonreciprocity

Abstract

Nonreciprocal theories are used to model a broad array of non-equilibrium phenomena found in nature ranging from biological systems like networks of neurons to the behavior of overflowing water fountains. This includes systems broadly classified as active matter systems. We show that the stochastic theories which describe nonreciprocal interactions can be mapped into quantum field theories described by a supersymmetric action with a single supercharge. The theories are generically non-Hermitian. This generalizes the past work of Parisi and Sourlas on reciprocal theories, which model systems with interactions derived from potentials.
Paper Structure (18 sections, 211 equations)

This paper contains 18 sections, 211 equations.

Table of Contents

  1. Introduction
  2. Stochastic ODEs and Supersymmetric Quantum Mechanics
  3. Formulating stochastic ODEs using the MSR path-integral
  4. Symmetries and the magic of reciprocity
  5. A supersymmetric description of nonreciprocal theories
  6. Euclidean Quantization
  7. Stochastic PDEs and Quantum Field Theory
  8. The reciprocal case and Parisi-Sourlas supersymmetry
  9. Nonreciprocal SPDEs and their field theory formulations
  10. Regularizing Stochastic Differential Equations (SDEs)
  11. Common choices of regularization
  12. The Fokker-Planck equation
  13. Ito and Stratonovich in the path integral
  14. Finite-dimensional Grassmann Integrals
  15. Representing determinants as real or complex Grassmanian integrals.
  16. ...and 3 more sections