Coherent-state propagation enables quasi-polynomial classical simulation of bosonic circuits with logarithmically many Kerr gates at exponentially small trace-distance error, with polynomial runtime in the weak-nonlinearity regime.
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6 Pith papers cite this work. Polarity classification is still indexing.
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UNVERDICTED 6representative citing papers
Endpoint Kirkwood-Dirac or Margenau-Hill quasistatistics of work retain sensitivity to initial coherence under imperfect shortcuts, exposing linear signatures of control errors where population probabilities show only quadratic changes.
Derives time-dependent voltage protocols that eliminate an arbitrary number of relaxation modes to accelerate charging and discharging of planar EDLCs in finite time shorter than intrinsic relaxation timescales.
A multi-step MA-STA control achieves high-fidelity driving of the Kitaev chain across its trivial-to-topological transition at times much shorter than linear protocols while reducing work fluctuations.
Presents a quantum Hamiltonian whose ground state encodes equivalence classes of expressions, enabling verification, counting, and structural queries on instances far beyond classical reach.
Introduces a framework for universal fully holonomic adiabatic gates in Rydberg atom systems with geometric robustness analysis.
citing papers explorer
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Coherent-State Propagation: A Computational Framework for Simulating Bosonic Quantum Systems
Coherent-state propagation enables quasi-polynomial classical simulation of bosonic circuits with logarithmically many Kerr gates at exponentially small trace-distance error, with polynomial runtime in the weak-nonlinearity regime.
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Shortcut-error signatures in coherence-retaining endpoint work quasistatistics
Endpoint Kirkwood-Dirac or Margenau-Hill quasistatistics of work retain sensitivity to initial coherence under imperfect shortcuts, exposing linear signatures of control errors where population probabilities show only quadratic changes.
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Accelerating charging dynamics of electric double-layer capacitors
Derives time-dependent voltage protocols that eliminate an arbitrary number of relaxation modes to accelerate charging and discharging of planar EDLCs in finite time shorter than intrinsic relaxation timescales.
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Minimal action shortcut to adiabaticity in a driven Kitaev chain: competing gaps in a topological transition at finite-time
A multi-step MA-STA control achieves high-fidelity driving of the Kitaev chain across its trivial-to-topological transition at times much shorter than linear protocols while reducing work fluctuations.
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Quantum algorithms for equational reasoning
Presents a quantum Hamiltonian whose ground state encodes equivalence classes of expressions, enabling verification, counting, and structural queries on instances far beyond classical reach.
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Holonomic quantum computation: a scalable adiabatic architecture
Introduces a framework for universal fully holonomic adiabatic gates in Rydberg atom systems with geometric robustness analysis.