Exact NESS of XXZ circuits boundary driven with arbitrary resets or fields
- URL: http://arxiv.org/abs/2502.06731v1
- Date: Mon, 10 Feb 2025 17:56:37 GMT
- Title: Exact NESS of XXZ circuits boundary driven with arbitrary resets or fields
- Authors: Vladislav Popkov, Tomaž Prosen,
- Abstract summary: The ansatz has formally infinite bond-dimension and is fundamentally different from previous constructions.
The circuit is driven by a pair of reset quantum channels applied on the boundary qubits, which polarize the qubits to arbitrary pure target states.
We obtain a family of relatively robust separable nonequilibrium steady states (NESS), which can be viewed as a circuit extension of spin-helix states.
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- Abstract: We propose spatially inhomogeneous matrix product ansatz for an exact many-body density operator of a boundary driven XXZ quantum circuit. The ansatz has formally infinite bond-dimension and is fundamentally different from previous constructions. The circuit is driven by a pair of reset quantum channels applied on the boundary qubits, which polarize the qubits to arbitrary pure target states. Moreover, one of the reset channels can be replaced by an arbitrary local unitary gate, thus representing a hybrid case with coherent/incoherent driving. Analyzing the ansatz we obtain a family of relatively robust separable nonequilibrium steady states (NESS), which can be viewed as a circuit extension of spin-helix states, and are particularly suited for experimental investigations.
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