An ETH-ansatz-based environmental-branch method derives master equations for open quantum systems by simplifying branch evolution over short time intervals, yielding decoherence rates consistent with random-matrix theory and justifying the Born approximation.
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Symmetric superpositions of antipodal triplet states produce exact zero-energy eigenstates in non-integrable spin Hamiltonians that are scars with tunable entanglement from volume to area law.
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An ETH-ansatz-motivated environmental-branch approach to open quantum systems
An ETH-ansatz-based environmental-branch method derives master equations for open quantum systems by simplifying branch evolution over short time intervals, yielding decoherence rates consistent with random-matrix theory and justifying the Born approximation.
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Symmetric tensor scars with tunable entanglement from volume to area law
Symmetric superpositions of antipodal triplet states produce exact zero-energy eigenstates in non-integrable spin Hamiltonians that are scars with tunable entanglement from volume to area law.