Exact steady states are derived for interacting dissipative fermionic systems with hidden time-reversal symmetry, revealing a first-order particle density phase transition that survives finite dissipation.
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quant-ph 2years
2026 2verdicts
UNVERDICTED 2representative citing papers
Decoherence leaves complementary quantum (cat-like state with Wigner negativity) and classical (Darwinian which-path) records in the bath, demonstrated via tensor-network simulations of a spin-boson model.
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Exact steady states of interacting driven dissipative fermionic systems with hidden time-reversal symmetry
Exact steady states are derived for interacting dissipative fermionic systems with hidden time-reversal symmetry, revealing a first-order particle density phase transition that survives finite dissipation.
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Complementary quantum and classical records of qubit decoherence
Decoherence leaves complementary quantum (cat-like state with Wigner negativity) and classical (Darwinian which-path) records in the bath, demonstrated via tensor-network simulations of a spin-boson model.