Magnon spin angular momentum in bilayer CrSBr is renormalized by anisotropy and dipolar interactions and diverges at field-induced softening, creating a peak in the thermal spin Seebeck effect.
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4 Pith papers cite this work. Polarity classification is still indexing.
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A minimally invasive pair of weak measurements on an atomic BEC yields the two-time density-density correlation function (Van Hove function) and its Fourier transform, the dynamical structure factor.
Quantized motion of trapped polar molecules realizes an asymmetric quantum Rabi model and trap-dipole resonance while supporting high-fidelity iSWAP and controlled-phase gates.
Simplified step-potential model shows critical velocity of BEC superflow minimized to zero at local condensation transition with v_c scaling as L_x to the power -0.963.
citing papers explorer
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Spin-caloritronic signatures of soft magnons in bilayer CrSBr
Magnon spin angular momentum in bilayer CrSBr is renormalized by anisotropy and dipolar interactions and diverges at field-induced softening, creating a peak in the thermal spin Seebeck effect.
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Repeated weak measurements: watching quantum correlations evolve
A minimally invasive pair of weak measurements on an atomic BEC yields the two-time density-density correlation function (Van Hove function) and its Fourier transform, the dynamical structure factor.
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Asymmetric quantum Rabi model, trap-dipole resonance, and quantum gates with optically trapped ultracold polar molecules
Quantized motion of trapped polar molecules realizes an asymmetric quantum Rabi model and trap-dipole resonance while supporting high-fidelity iSWAP and controlled-phase gates.
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Anomalous minimization for critical velocity of superflow along a step potential
Simplified step-potential model shows critical velocity of BEC superflow minimized to zero at local condensation transition with v_c scaling as L_x to the power -0.963.