Noisy IBM quantum circuits reproduce short-time population dynamics of a biased exciton dimer against HEOM benchmarks, with fitted parameters showing linear dependence on noisy-gate frequency to enable interpolation, extended via TTM.
Simulation of thermal relaxation in spin chemistry systems on a quantum computer using inherent qubit decoherence
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Qudit encoding of the vibrational Hamiltonian yields the most accurate population transfer simulations for CO2 and H2O compared to binary and direct qubit encodings when entangling gate error rates are held equal.
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Quantum Simulation of Dissipative Energy Transfer via Noisy Quantum Computer
Noisy IBM quantum circuits reproduce short-time population dynamics of a biased exciton dimer against HEOM benchmarks, with fitted parameters showing linear dependence on noisy-gate frequency to enable interpolation, extended via TTM.
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Simulation of vibrational dynamics using qubits and qudits
Qudit encoding of the vibrational Hamiltonian yields the most accurate population transfer simulations for CO2 and H2O compared to binary and direct qubit encodings when entangling gate error rates are held equal.