SesQ applies surface discretization and a semi-analytical multilayer Green's function to calculate EPR in qubits with roughly 100x faster capacitance extraction and higher precision than volumetric FEM.
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Relative motion between two Dirac plates with nonlocal interaction induces vacuum excitations and dissipative forces with a velocity threshold via perturbative effective action.
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SesQ: A Surface Electrostatic Simulator for Precise Energy Participation Ratio Simulation in Superconducting Qubits
SesQ applies surface discretization and a semi-analytical multilayer Green's function to calculate EPR in qubits with roughly 100x faster capacitance extraction and higher precision than volumetric FEM.
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Motion-driven quantum dissipation in an open electronic system with nonlocal interaction
Relative motion between two Dirac plates with nonlocal interaction induces vacuum excitations and dissipative forces with a velocity threshold via perturbative effective action.