An optimization framework for high-efficiency quantum Feshbach engines in trapped BECs is developed using variational dynamics and Nelson's stochastic quantization to minimize cost functionals for protocol duration versus physical constraints.
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Shear viscosity in ultracold Fermi gases varies by orders of magnitude near the BCS-BEC crossover, enabling tunable high-Reynolds-number flows.
Saturation of collisional resistivity to an interaction-independent value is observed in strongly interacting ultracold fermions in a 3D lattice and captured by a renormalized two-body scattering model.
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Optimal Quantum Feshbach Engines
An optimization framework for high-efficiency quantum Feshbach engines in trapped BECs is developed using variational dynamics and Nelson's stochastic quantization to minimize cost functionals for protocol duration versus physical constraints.
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Tunable viscosity across the BCS-BEC crossover
Shear viscosity in ultracold Fermi gases varies by orders of magnitude near the BCS-BEC crossover, enabling tunable high-Reynolds-number flows.
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Lattice Unitarity: Saturated Collisional Resistivity in Hubbard Metals
Saturation of collisional resistivity to an interaction-independent value is observed in strongly interacting ultracold fermions in a 3D lattice and captured by a renormalized two-body scattering model.