Open quantum systems and the grand canonical ensemble
- URL: http://arxiv.org/abs/2508.16985v1
- Date: Sat, 23 Aug 2025 10:51:59 GMT
- Title: Open quantum systems and the grand canonical ensemble
- Authors: Benedikt M. Reible, Luigi Delle Site,
- Abstract summary: The celebrated Lindblad equation governs the non-unitary time evolution of density operators in quantum systems.<n>We investigate the compatibility of grand canonical statistical mechanics with the derivation of the Lindblad equation.
- Score: 0.0
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: The celebrated Lindblad equation governs the non-unitary time evolution of density operators used in the description of open quantum systems. It is usually derived from the von Neumann equation for a large system, at given physical conditions, when a small subsystem is explicitly singled out and the rest of the system acts as an environment whose degrees of freedom are traced out. In the specific case of a subsystem with variable particle number, the equilibrium density operator is given by the well-known grand canonical Gibbs state. Consequently, solving the Lindblad equation in this case should automatically yield, without any additional assumptions, the corresponding density operator in the limiting case of statistical equilibrium. Current studies of the Lindblad equation with varying particle number assume, however, the grand canonical Gibbs state a priori: the chemical potential is externally imposed rather than derived from first principles, and hence the corresponding density operator is not obtained as a natural solution of the equation. In this work, we investigate the compatibility of grand canonical statistical mechanics with the derivation of the Lindblad equation. We propose an alternative and complementary approach to the current literature that consists in using a generalized system Hamiltonian which includes a term $\mu N$. In a previous paper, this empirically well-known term has been formally derived from the von Neumann equation for the specific case of equilibrium. Including $\mu N$ in the system Hamiltonian leads to a modified Lindblad equation which yields the grand canonical state as a natural solution, meaning that all the quantities involved are obtained from the physics of the system without any external assumptions.
Related papers
- Boltzmann to Lindblad: Classical and Quantum Approaches to Out-of-Equilibrium Statistical Mechanics [0.8351309125845637]
Open quantum systems play a central role in nanoscale technologies, including molecular electronics, quantum heat engines, quantum computation information processing.<n>A major theoretical challenge is to construct dynamical models that are simultaneously consistent with classical thermodynamics and complete positivity.<n>We develop a framework that addresses this issue by extending classical dynamics to the quantum domain.
arXiv Detail & Related papers (2025-12-12T14:50:28Z) - Polynomial Time Quantum Gibbs Sampling for Fermi-Hubbard Model at any Temperature [9.62464358196899]
We prove a constant gap of the perturbed Lindbladian corresponding to interacting fermions up to some maximal coupling strength.<n>This is achieved by using theorems about stability of the gap for lattice fermions.<n>As an application, we explain how to calculate partition functions for the considered systems.
arXiv Detail & Related papers (2025-01-02T18:56:02Z) - Susceptibility of entanglement entropy: a universal indicator of quantum criticality [11.049672162852735]
A measure of how sensitive the entanglement entropy is in a quantum system, has been proposed and its information origin is discussed.<n>It has been demonstrated for two exactly solvable spin systems, that thermodynamic criticality is directly textitindicated by finite size scaling of the global maxima.
arXiv Detail & Related papers (2024-12-03T08:04:58Z) - Solving the Lindblad equation with methods from computational fluid dynamics [0.0]
Liouvillian dynamics describes the evolution of a density operator in closed quantum systems.
One extension towards open quantum systems is provided by the Lindblad equation.
Main challenge is that analytical solutions for the Lindblad equation are only obtained for harmonic system potentials or two-level systems.
arXiv Detail & Related papers (2024-10-14T14:24:23Z) - Lindbladian reverse engineering for general non-equilibrium steady states: A scalable null-space approach [49.1574468325115]
We introduce a method for reconstructing the corresponding Lindbaldian master equation given any target NESS.
The kernel (null-space) of the correlation matrix corresponds to Lindbladian solutions.
We illustrate the method in different systems, ranging from bosonic Gaussian to dissipative-driven collective spins.
arXiv Detail & Related papers (2024-08-09T19:00:18Z) - Stability of Quantum Systems beyond Canonical Typicality [9.632520418947305]
We analyze the statistical distribution of a quantum system coupled strongly with a heat bath.
The stability of system distribution is largely affected by the system--bath interaction strength.
arXiv Detail & Related papers (2024-07-22T02:59:04Z) - Probabilistic Unitary Formulation of Open Quantum System Dynamics [1.8416014644193066]
We show that all non-relativistic quantum processes, whether open or closed, are unitary or probabilistic unitary.<n>For open quantum systems, its continuous dynamics can always be described by the Lindblad master equation with all jump operators being unitary.<n>This formalism is shown to be exact under all cases, and does not rely on any assumptions other than the continuity and differentiability of the density matrix.
arXiv Detail & Related papers (2023-07-11T20:07:03Z) - Local Non-Hermitian Hamiltonian Formalism for Dissipative Fermionic Systems and Loss-Induced Population Increase in Fermi Superfluids [12.09844466815655]
We present a framework called the local NHH formalism, which describes the loss process in each individual mode locally.<n>The local NHH formalism also provides a convenient framework for studying non-Hermitian physics in dissipative fermionic systems.
arXiv Detail & Related papers (2023-06-28T13:57:18Z) - Canonically consistent quantum master equation [68.8204255655161]
We put forth a new class of quantum master equations that correctly reproduce the state of an open quantum system beyond the infinitesimally weak system-bath coupling limit.
Our method is based on incorporating the knowledge of the reduced steady state into its dynamics.
arXiv Detail & Related papers (2022-05-25T15:22:52Z) - Non-diagonal Lindblad master equations in quantum reservoir engineering [0.0]
We present a set of dynamical equations for the first and second moments of canonical variables for bosonic and fermionic linear Gaussian systems.
Our method is efficient and allows one to obtain analytical solutions for the steady state.
Our exploration yields a surprising byproduct: the Duan criterion, commonly applied to bosonic systems for verification of entanglement, is found to be equally valid for fermionic systems.
arXiv Detail & Related papers (2021-11-07T09:55:04Z) - A canonical Hamiltonian for open quantum systems [1.52292571922932]
We study the division of open system dynamics into unitary and dissipative pieces.
For finite-dimensional quantum systems, we specify a norm on the space of dissipative superoperators.
We show that the canonical Hamiltonian is equivalent to the Hamiltonian initially defined by Lindblad.
arXiv Detail & Related papers (2021-08-18T18:00:19Z) - Linear growth of the entanglement entropy for quadratic Hamiltonians and
arbitrary initial states [11.04121146441257]
We prove that the entanglement entropy of any pure initial state of a bosonic quantum system grows linearly in time.
We discuss several applications of our results to physical systems with (weakly) interacting Hamiltonians and periodically driven quantum systems.
arXiv Detail & Related papers (2021-07-23T07:55:38Z) - Entanglement Measures in a Nonequilibrium Steady State: Exact Results in
One Dimension [0.0]
Entanglement plays a prominent role in the study of condensed matter many-body systems.
We show that the scaling of entanglement with the length of a subsystem is highly unusual, containing both a volume-law linear term and a logarithmic term.
arXiv Detail & Related papers (2021-05-03T10:35:09Z) - Bernstein-Greene-Kruskal approach for the quantum Vlasov equation [91.3755431537592]
The one-dimensional stationary quantum Vlasov equation is analyzed using the energy as one of the dynamical variables.
In the semiclassical case where quantum tunneling effects are small, an infinite series solution is developed.
arXiv Detail & Related papers (2021-02-18T20:55:04Z)
This list is automatically generated from the titles and abstracts of the papers in this site.
This site does not guarantee the quality of this site (including all information) and is not responsible for any consequences.