Adjusting quantum gate timing via scheduling suppresses idling errors and improves accuracy in simulations and hardware experiments without added gates, supported by an analytical density-matrix derivation.
Robust ultra-shallow shadows
11 Pith papers cite this work. Polarity classification is still indexing.
citation-role summary
citation-polarity summary
fields
quant-ph 11years
2026 11verdicts
UNVERDICTED 11roles
background 3polarities
background 3representative citing papers
Introduces Λ-lr-QAOA and piecewise-ramp QAOA that promote penalty schedules to variational parameters and use a feasibility-driven loss on budget-constrained MWIS satellite planning instances.
Pulse-optimized implementations of single- and double-qubit excitations in VQE reduce runtimes by up to 15.3 times on silicon spin-qubit processors.
Heuristic and RL-based adaptive shot allocation in recursive QAOA reduces total shots by 23-36% compared to uniform allocation on weighted Max-Cut instances.
Three scheduling strategies for hybrid quantum-HPC systems cut classical resource use by up to 64% or boost QPU utilization depending on workload balance, validated on real hardware.
Dissipative dynamics activate finite ergotropy from thermal quantum spin chains, with collective effects creating temperature- and size-dependent steady-state passivity via dark subspaces, while dephasing suppresses extraction.
Local robust shadows with calibration stages and Pauli-X-twirling mitigate errors from shortened measurement pulses on trapped-ion hardware for Haar random and QAOA states.
A design study outlines how detector-grade Ge with ~2e14 cm^-3 In acceptors could enable a statistically selected five-qubit register with all-electrical control and manageable disorder.
A surface ion trap design with multiple trapping regions enables high-sensitivity magnetic field mapping and gradiometry using trapped ions.
A literature survey of microwave-optical transduction across three platforms with two proposed normalized metrics for cross-platform comparison of efficiency and noise.
Review synthesizing crosstalk mechanisms, mitigation strategies, and security vulnerabilities across major quantum computing platforms from existing literature.
citing papers explorer
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Idling error suppression through gate scheduling
Adjusting quantum gate timing via scheduling suppresses idling errors and improves accuracy in simulations and hardware experiments without added gates, supported by an analytical density-matrix derivation.
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Feasibility-driven QAOA with penalty scheduling
Introduces Λ-lr-QAOA and piecewise-ramp QAOA that promote penalty schedules to variational parameters and use a feasibility-driven loss on budget-constrained MWIS satellite planning instances.
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Pulse-optimised circuit elements for scalable and noise-resilient quantum chemistry
Pulse-optimized implementations of single- and double-qubit excitations in VQE reduce runtimes by up to 15.3 times on silicon spin-qubit processors.
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Adaptive Shot Allocation for Recursive QAOA via Reinforcement Learning
Heuristic and RL-based adaptive shot allocation in recursive QAOA reduces total shots by 23-36% compared to uniform allocation on weighted Max-Cut instances.
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Three ways to share a QPU: Scheduling strategies for hybrid Quantum-HPC applications
Three scheduling strategies for hybrid quantum-HPC systems cut classical resource use by up to 64% or boost QPU utilization depending on workload balance, validated on real hardware.
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Charging Quantum Batteries via Dissipative Quenches
Dissipative dynamics activate finite ergotropy from thermal quantum spin chains, with collective effects creating temperature- and size-dependent steady-state passivity via dark subspaces, while dephasing suppresses extraction.
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Local robust shadows on a trapped ion computer -- a case study
Local robust shadows with calibration stages and Pauli-X-twirling mitigate errors from shortened measurement pulses on trapped-ion hardware for Haar random and QAOA states.
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Detector-Grade Germanium as a Low-Disorder Host for Indium-Acceptor Spin Qubits: A Five-Qubit Materials-to-Architecture Design Study
A design study outlines how detector-grade Ge with ~2e14 cm^-3 In acceptors could enable a statistically selected five-qubit register with all-electrical control and manageable disorder.
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Scalable surface ion trap design for magnetic quantum sensing and gradiometry
A surface ion trap design with multiple trapping regions enables high-sensitivity magnetic field mapping and gradiometry using trapped ions.
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Toward Scalable Heterogeneous Quantum Networks: Microwave-Optical Transduction Across Platforms
A literature survey of microwave-optical transduction across three platforms with two proposed normalized metrics for cross-platform comparison of efficiency and noise.
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Crosstalk In Contemporary Quantum Devices
Review synthesizing crosstalk mechanisms, mitigation strategies, and security vulnerabilities across major quantum computing platforms from existing literature.