Spin-boson decoherence imprints Wigner-negative nonclassicality on a mapped collective bosonic reservoir coordinate visible only after conditional qubit readout.
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9 Pith papers cite this work. Polarity classification is still indexing.
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UNVERDICTED 9representative citing papers
Weak Gaussian noise in control fields makes dissipation grow linearly with steps in quantum equilibration, yielding a finite optimal step count and minimal dissipated work derived from quantum thermodynamic length.
Proposes coherence-gated photon routing via real-time weak measurements of qubit coherence, enabling bounded-entropy RNG and entanglement fidelity certification.
Successive quantum feedback control with non-adaptive bare measurements collapses to the ten AZ† symmetry classes that dictate topology of CPTP maps, demonstrated via quantized winding numbers in a chiral demon and an explicit protocol outside the classes.
Defines a Pauli-constraint model of quantum circuits proven equivalent to coupling-graph-restricted circuits, universal for BQP with O(D² N log N) overhead.
Interference between local measurement histories on two qubits generates entanglement, persisting even after averaging over detector readouts.
Stratonovich rather than Ito stochastic noise agrees with experiment for the measured homodyne current in broad-band SSE simulations of EPR quantum trajectories.
Language generation requires dissipative quantum dynamics with non-local aggregation, not conservation laws, framing it as dissipative quantum field theory.
Derives closed-form expressions for squeezing, second-order correlation, and joint spectral intensity between signal and idler modes in quantum frequency combs from microring resonators.
citing papers explorer
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Propagation of conditional nonclassical reservoir states during quantum decoherence
Spin-boson decoherence imprints Wigner-negative nonclassicality on a mapped collective bosonic reservoir coordinate visible only after conditional qubit readout.
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Finite steps optimise dissipation in stochastically controlled quantum systems
Weak Gaussian noise in control fields makes dissipation grow linearly with steps in quantum equilibration, yielding a finite optimal step count and minimal dissipated work derived from quantum thermodynamic length.
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Coherence-gated quantum devices via real-time weak measurement
Proposes coherence-gated photon routing via real-time weak measurements of qubit coherence, enabling bounded-entropy RNG and entanglement fidelity certification.
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Symmetry and Topology of Successive Quantum Feedback Control
Successive quantum feedback control with non-adaptive bare measurements collapses to the ten AZ† symmetry classes that dictate topology of CPTP maps, demonstrated via quantized winding numbers in a chiral demon and an explicit protocol outside the classes.
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Quantum circuit design via dynamic Pauli constraints
Defines a Pauli-constraint model of quantum circuits proven equivalent to coupling-graph-restricted circuits, universal for BQP with O(D² N log N) overhead.
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Interference of local-measurement histories
Interference between local measurement histories on two qubits generates entanglement, persisting even after averaging over detector readouts.
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Physical currents for stochastic Einstein-Podolsky-Rosen quantum trajectories
Stratonovich rather than Ito stochastic noise agrees with experiment for the measured homodyne current in broad-band SSE simulations of EPR quantum trajectories.
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Path Integral Solution for Dissipative Generative Dynamics
Language generation requires dissipative quantum dynamics with non-local aggregation, not conservation laws, framing it as dissipative quantum field theory.
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Steady-state dynamics of quantum frequency combs in microring resonators
Derives closed-form expressions for squeezing, second-order correlation, and joint spectral intensity between signal and idler modes in quantum frequency combs from microring resonators.