A new microscopic model maps quantum dot device geometry directly to flopping-mode qubit parameters, reveals a tradeoff between fast electric driving and clean Rabi oscillations, and derives exchange coupling for capacitively coupled qubits.
Semiconductor spin qubits,
9 Pith papers cite this work. Polarity classification is still indexing.
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representative citing papers
Pulse-optimized implementations of single- and double-qubit excitations in VQE reduce runtimes by up to 15.3 times on silicon spin-qubit processors.
Near a valley level anti-crossing in a Si-MOS quantum dot, inter-valley spin coupling activates an electric-dipole transition that enhances the electron spin Rabi frequency.
Spin-qubit operation is framed as a modular automation problem with five modules to enable scalable stable arrays via interfaces, standardized data products, and workflow metrics.
Reports experimental generation of remote Bell entanglement between two giant atoms with fidelity 0.89 using driven-dissipative stabilization and in-situ frequency tuning.
Numerical study demonstrates controlled transport of Z4 parafermion edge states in a ladder model and quantifies the adiabatic speed limit under realistic conditions.
Fast gate-based reflectometry readout of Pauli spin blockade and tunable interdot coupling demonstrated in industry-fabricated silicon double quantum dots.
A synthesis of expert insights from the ADAC Quantum Computing Working Group and member survey on the complementary roles of quantum and classical high-performance computing in future hybrid infrastructures.
citing papers explorer
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Microscopic modeling of flopping-mode quantum dot spin qubits
A new microscopic model maps quantum dot device geometry directly to flopping-mode qubit parameters, reveals a tradeoff between fast electric driving and clean Rabi oscillations, and derives exchange coupling for capacitively coupled qubits.
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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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Valley enhanced Rabi frequency in n-type planar Silicon-MOS quantum dot
Near a valley level anti-crossing in a Si-MOS quantum dot, inter-valley spin coupling activates an electric-dipole transition that enhances the electron spin Rabi frequency.
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Overcoming Configuration Bottleneck: Modular Pathways to Stable Semiconductor Spin-Qubit Arrays
Spin-qubit operation is framed as a modular automation problem with five modules to enable scalable stable arrays via interfaces, standardized data products, and workflow metrics.
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Driven-dissipative entanglement of distant giant atoms
Reports experimental generation of remote Bell entanglement between two giant atoms with fidelity 0.89 using driven-dissipative stabilization and in-situ frequency tuning.
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Shuttling of $\mathbb{Z}_4$ parafermions in an electronic ladder model
Numerical study demonstrates controlled transport of Z4 parafermion edge states in a ladder model and quantifies the adiabatic speed limit under realistic conditions.
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Fast readout for large scale spin-based qubits
Fast gate-based reflectometry readout of Pauli spin blockade and tunable interdot coupling demonstrated in industry-fabricated silicon double quantum dots.
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The Role of Quantum Computing in Advancing Scientific High-Performance Computing: A perspective from the ADAC Institute
A synthesis of expert insights from the ADAC Quantum Computing Working Group and member survey on the complementary roles of quantum and classical high-performance computing in future hybrid infrastructures.
- Simulation of Two-qubit Gate Variability and Fidelity of Spin Qubits Built on Nanosheet Technology