A Slater-determinant-to-qubit mapping enables low-depth VQE circuits for nuclear shell model calculations on NISQ hardware, achieving less than 4% deviation from classical predictions after zero-noise extrapolation for nuclei including lithium isotopes and 210Pb.
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Shell model calculations with bounded fluctuations in two-body matrix elements and Bayesian model averaging produce a 76Ge 0νββ nuclear matrix element of 2.46 with standard deviation 0.25.
Optimized VQE variants with Gray code encoding and zero-noise extrapolation achieve improved accuracy for nuclear shell-model energies of 38Ar and 6Li in noisy simulations.
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A low-circuit-depth quantum computing approach to the nuclear shell model
A Slater-determinant-to-qubit mapping enables low-depth VQE circuits for nuclear shell model calculations on NISQ hardware, achieving less than 4% deviation from classical predictions after zero-noise extrapolation for nuclei including lithium isotopes and 210Pb.
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Uncertainty Quantification of the $^{76}$Ge Neutrinoless Double-Beta Decay Nuclear Matrix Element
Shell model calculations with bounded fluctuations in two-body matrix elements and Bayesian model averaging produce a 76Ge 0νββ nuclear matrix element of 2.46 with standard deviation 0.25.
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Advancing quantum simulations of nuclear shell model with noise-resilient protocols
Optimized VQE variants with Gray code encoding and zero-noise extrapolation achieve improved accuracy for nuclear shell-model energies of 38Ar and 6Li in noisy simulations.