Matrix product states allow amplitude encoding of Slater-type orbitals with constant bond dimension in one dimension and saturating entanglement in three dimensions, supporting low-error integral evaluation on quantum processors.
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A framework for 2D thermal metamaterials identifies a two-channel transport mechanism where coherent nonlinear excitations coexist with incoherent modes, sensitive to geometry and nonlinearity.
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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Amplitude Encoding of Slater-Type Orbitals via Matrix Product States: Efficient State Preparation and Integral Evaluation on Quantum Hardware
Matrix product states allow amplitude encoding of Slater-type orbitals with constant bond dimension in one dimension and saturating entanglement in three dimensions, supporting low-error integral evaluation on quantum processors.
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Nonlinear Coherent Transport in 2D Thermal Metamaterials: From Solitons and Topological Defects to Quantum Computing
A framework for 2D thermal metamaterials identifies a two-channel transport mechanism where coherent nonlinear excitations coexist with incoherent modes, sensitive to geometry and nonlinearity.
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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.