Local Non-Hermitian Hamiltonian Formalism for Dissipative Fermionic Systems and Loss-Induced Population Increase in Fermi Superfluids

TL;DR

This paper introduces a local non-Hermitian Hamiltonian formalism for dissipative fermionic systems, overcoming limitations of traditional approaches, and demonstrates its effectiveness through analysis of loss-induced population increase in Fermi superfluids.

Contribution

The paper proposes a local NHH formalism that accurately models dissipation in fermionic systems, maintaining consistency with the Lindblad equation and capturing phenomena missed by conventional methods.

Findings

Local NHH formalism accurately describes fermionic dissipation.

Conventional NHH fails to capture loss-induced population increase.

Application to Fermi superfluids reveals phase locking effects.

Abstract

We examine a standard scheme to obtain the non-Hermitian Hamiltonian (NHH) from the Lindblad master equation by neglecting its jump term, and propose an alternative approach to address the limitations of the former. It is shown that the NHH obtained by the conventional scheme fails to provide a good approximation for fermionic many-body systems, even on short timescales. To resolve this issue, we present a framework called the local NHH formalism, which describes the loss process in each individual mode locally. This formalism is applicable to general dissipative fermionic systems and remains consistent with the underlying Lindblad master equation at the level of the equations of motion of local observables. The local NHH formalism also provides a convenient framework for studying non-Hermitian physics in dissipative fermionic systems, especially for spectral analysis, compared to the Lindblad master equation. As an illustration, we consider a fermionic superfluid subjected to one-body loss and find the population increase induced by the loss, resulting from the locking of the relative phase between the pairing gap and the anomalous field. The conventional NHH fails to capture these unique phenomena.