A circular-modulated concatenated continuous driving (CMCCD) protocol for silicon qubits cancels counter-rotating errors via dual modulation and shows higher simulated fidelity plus improved experimental robustness to detuning and Rabi errors compared to standard Rabi or prior CCD drives.
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Constructive protocols prove that arbitrary fermionic quantum operations are achievable with global controls in optical lattice Fermi-Hubbard systems.
Classical simulation of quantum annealing for the 1D Hubbard model up to 40 qubits reports substantial speed-up over Bethe-ansatz methods for half-filled cases.
citing papers explorer
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Concatenated continuous driving of silicon qubit by amplitude and phase modulation
A circular-modulated concatenated continuous driving (CMCCD) protocol for silicon qubits cancels counter-rotating errors via dual modulation and shows higher simulated fidelity plus improved experimental robustness to detuning and Rabi errors compared to standard Rabi or prior CCD drives.
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Programmable Fermionic Quantum Processors with Globally Controlled Lattices
Constructive protocols prove that arbitrary fermionic quantum operations are achievable with global controls in optical lattice Fermi-Hubbard systems.
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Quantum speed-up for solving the one-dimensional Hubbard model using quantum annealing
Classical simulation of quantum annealing for the 1D Hubbard model up to 40 qubits reports substantial speed-up over Bethe-ansatz methods for half-filled cases.