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Auteurs principaux: Lausdei, Enrica, Pajer, Enrico
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2605.23375
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author Lausdei, Enrica
Pajer, Enrico
author_facet Lausdei, Enrica
Pajer, Enrico
contents Open effective field theories provide a systematic framework for describing physical systems interacting with an environment whose microscopic details are unknown, unobservable, or uncalculable. A basic step in constructing any effective field theory is the identification of the relevant degrees of freedom. For open effective theories, however, this step is subtle: their dynamics is generically dissipative and non-Hamiltonian, so the standard Hamiltonian and Lagrangian algorithms are not directly applicable. To overcome this limitation, we develop an algorithm to count degrees of freedom directly from the equations of motion. Restricting to classical, linearised dynamics on homogeneous and isotropic backgrounds, our method applies to non-Lagrangian systems with unequal numbers of fields and equations, including systems with constraints and gauge redundancies. As a by-product, our algorithm identifies constraints, gauge identities, gauge redundancies, and consistency conditions on stochastic sources. The central ingredient is the introduction of a dual set of ``advanced'' equations, or equivalently an auxiliary Martin-Siggia-Rose functional. We show that gauge redundancies of the original fields are associated with gauge identities of the dual advanced equations, and vice versa. We illustrate our procedure in examples ranging from coupled scalar systems to electromagnetism in a medium and gravitational effective theories relevant for cosmology. Our results will prove useful in the study of stochastic dynamics, non-equilibrium statistical systems and the semi-classical limit of open quantum systems on the Schwinger-Keldysh path integral.
format Preprint
id arxiv_https___arxiv_org_abs_2605_23375
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Counting Degrees of Freedom in Open Effective Theories
Lausdei, Enrica
Pajer, Enrico
High Energy Physics - Theory
Open effective field theories provide a systematic framework for describing physical systems interacting with an environment whose microscopic details are unknown, unobservable, or uncalculable. A basic step in constructing any effective field theory is the identification of the relevant degrees of freedom. For open effective theories, however, this step is subtle: their dynamics is generically dissipative and non-Hamiltonian, so the standard Hamiltonian and Lagrangian algorithms are not directly applicable. To overcome this limitation, we develop an algorithm to count degrees of freedom directly from the equations of motion. Restricting to classical, linearised dynamics on homogeneous and isotropic backgrounds, our method applies to non-Lagrangian systems with unequal numbers of fields and equations, including systems with constraints and gauge redundancies. As a by-product, our algorithm identifies constraints, gauge identities, gauge redundancies, and consistency conditions on stochastic sources. The central ingredient is the introduction of a dual set of ``advanced'' equations, or equivalently an auxiliary Martin-Siggia-Rose functional. We show that gauge redundancies of the original fields are associated with gauge identities of the dual advanced equations, and vice versa. We illustrate our procedure in examples ranging from coupled scalar systems to electromagnetism in a medium and gravitational effective theories relevant for cosmology. Our results will prove useful in the study of stochastic dynamics, non-equilibrium statistical systems and the semi-classical limit of open quantum systems on the Schwinger-Keldysh path integral.
title Counting Degrees of Freedom in Open Effective Theories
topic High Energy Physics - Theory
url https://arxiv.org/abs/2605.23375