Surface code logical qubits in continuous baths have a true thermodynamic error threshold only for short-range interactions, as their decoherence maps exactly to the anisotropic Kondo model.
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The geometry of a symmetry landscape in covariance space determines whether wave packets in linear open quantum systems diffuse, localize, or collapse at long times.
Functional renormalization group analysis of the 1D dissipative Bose-Hubbard model reveals a Luttinger-liquid line of fixed points competing with a dissipative fixed point of finite compressibility and vanishing superfluid stiffness, separated by a BKT transition, for ohmic to super-ohmic baths.
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Quantum Decoherence of the Surface Code: A Generalized Caldeira-Leggett Approach
Surface code logical qubits in continuous baths have a true thermodynamic error threshold only for short-range interactions, as their decoherence maps exactly to the anisotropic Kondo model.
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Wave packet landscape in linear open quantum systems
The geometry of a symmetry landscape in covariance space determines whether wave packets in linear open quantum systems diffuse, localize, or collapse at long times.
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Functional renormalization group study of a dissipative Bose--Hubbard model
Functional renormalization group analysis of the 1D dissipative Bose-Hubbard model reveals a Luttinger-liquid line of fixed points competing with a dissipative fixed point of finite compressibility and vanishing superfluid stiffness, separated by a BKT transition, for ohmic to super-ohmic baths.