Exact description of quantum stochastic models as quantum resistors

TL;DR

This paper introduces a new method to exactly analyze transport in out-of-equilibrium quantum systems with noise, revealing diffusive regimes and phase transitions in various fermionic models.

Contribution

The authors develop an exact solution framework for quantum stochastic Hamiltonians, extending transport analysis to finite temperatures and long-range hopping.

Findings

Exact solutions for quantum stochastic models confirm diffusive behavior.

Finite temperature effects on conductance are characterized.

Discovery of a ballistic-to-diffusive transition driven by hopping range.

Abstract

We study the transport properties of generic out-of-equilibrium quantum systems connected to fermionic reservoirs. We develop a new method, based on an expansion of the current in terms of the inverse system size and out of equilibrium formulations such as the Keldysh technique and the Meir-Wingreen formula. Our method allows a simple and compact derivation of the current for a large class of systems showing diffusive/ohmic behavior. In addition, we obtain exact solutions for a large class of quantum stochastic Hamiltonians (QSHs) with time and space dependent noise, using a self consistent Born diagrammatic method in the Keldysh representation. We show that these QSHs exhibit diffusive regimes which are encoded in the Keldysh component of the single particle Green's function. The exact solution for these QSHs models confirms the validity of our system size expansion ansatz, and its efficiency in capturing the transport properties. We consider in particular three fermionic models: i) a model with local dephasing ii) the quantum simple symmetric exclusion process model iii) a model with long-range stochastic hopping. For i) and ii) we compute the full temperature and dephasing dependence of the conductance of the system, both for two- and four-points measurements. Our solution gives access to the regime of finite temperature of the reservoirs which could not be obtained by previous approaches. For iii), we unveil a novel ballistic-to-diffusive transition governed by the range and the nature (quantum or classical) of the hopping. As a by-product, our approach equally describes the mean behavior of quantum systems under continuous measurement.