Stationary states of boundary driven quantum systems: some exact results
| Autor: | Carlen, Eric A., Huse, David a., Lebowitz, Joel L. |
|---|---|
| Rok vydání: | 2024 |
| Předmět: | |
| Druh dokumentu: | Working Paper |
| Popis: | We study finite-dimensional open quantum systems whose density matrix evolves via a Lindbladian, $\dot{\rho}=-i[H,\rho]+{\mathcal D}\rho$. Here $H$ is the Hamiltonian of the isolated system and ${\mathcal D}$ is the dissipator. We consider the case where the system consists of two parts, the "boundary'' $A$ and the ``bulk'' $B$, and ${\mathcal D}$ acts only on $A$, so ${\mathcal D}={\mathcal D}_A\otimes{\mathcal I}_B$, where ${\mathcal D}_A$ acts only on part $A$, while ${\mathcal I}_B$ is the identity superoperator on part $B$. Let ${\mathcal D}_A$ be ergodic, so ${\mathcal D}_A\hat{\rho}_A=0$ only for one unique density matrix $\hat{\rho}_A$. We show that any stationary density matrix $\bar{\rho}$ on the full system which commutes with $H$ must be of the product form $\bar{\rho}=\hat{\rho}_A\otimes\rho_B$ for some $\rho_B$. This rules out finding any ${\mathcal D}_A$ that has the Gibbs measure $\rho_\beta\sim e^{-\beta H}$ as a stationary state with $\beta\neq 0$, unless there is no interaction between parts $A$ and $B$. We give criteria for the uniqueness of the stationary state $\bar{\rho}$ for systems with interactions between $A$ and $B$. Related results for non-ergodic cases are also discussed. Comment: This version corrects a few typos |
| Databáze: | arXiv |
| Externí odkaz: |
|