First realization of the ν=1/3 fermionic Laughlin state on a 16-qubit IonQ trapped-ion processor via Hamiltonian variational ansatz and symmetry-verification error mitigation, matching exact diagonalization.
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A boson-sampling variational ansatz paired with classical post-processing reaches chemical accuracy on molecular potential energy curves using linear optics.
A gate freezing method improves convergence of gradient-free optimizers Rotosolve, Fraxis, and FQS for parameterized quantum circuits by reallocating resources to poorly optimized gates using previous iteration information.
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Realization of fermionic Laughlin state on a quantum processor
First realization of the ν=1/3 fermionic Laughlin state on a 16-qubit IonQ trapped-ion processor via Hamiltonian variational ansatz and symmetry-verification error mitigation, matching exact diagonalization.
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Boson sampling enhanced quantum chemistry
A boson-sampling variational ansatz paired with classical post-processing reaches chemical accuracy on molecular potential energy curves using linear optics.
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Gate Freezing Method for Gradient-Free Variational Quantum Algorithms in Circuit Optimization
A gate freezing method improves convergence of gradient-free optimizers Rotosolve, Fraxis, and FQS for parameterized quantum circuits by reallocating resources to poorly optimized gates using previous iteration information.