Boundary-driven quantum systems near the Zeno limit: steady states and long-time behavior
Abstract
We study composite open quantum systems with a finite-dimensional state space HA HB governed by a Lindblad equation '(t) = Lγ (t) where Lγ = -i[H,] + γ D , and D is a dissipator DA I acting non-trivially only on part A of the system, which can be thought of as the boundary, and γ is a parameter. It is known that the dynamics simplifies for large γ: after a time of order γ-1, (t) is well approximated for times small compared to γ2 by πA R(t) where πA is a steady state of DA, and R(t) is a solution of d dtR(t) = LP,γR(t) where LP,γ R := -i[HP,R] + γ-1 DP R with HP being a Hamiltonian on HB and DP being a Lindblad generator over HB. We prove this assuming only that DA is ergodic and gapped. In order to better control the long time behavior, and study the steady states γ, we introduce a third Lindblad generator DP that does not involve γ, but still closely related to Lγ. We show that if DP is ergodic and gapped, then so is Lγ for all large γ, and if γ denotes the unique steady state for Lγ, then γ∞γ = πA R where R is the unique steady state for DP. We show that there is a convergent expansion γ = πA R +γ-1 Σk=0∞ γ-k nk where, defining n-1 := πA R, D nk = -i[H, nk-1] for all k≥ 0.
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