First creation of ultracold heteronuclear p-wave Feshbach molecules in a Na-Rb Bose-Bose mixture via magneto-association and resonance characterization.
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Temperature-controlled resonance arises in heteronuclear mixtures when thermal smearing reshapes the effective potential, shifting resonance position with temperature.
Neural network quantum states compute Efimov bound states for 3-6 boson systems and mass-imbalanced fermions at unitarity, matching known energies and reproducing scale invariance and wave function features.
A vibrational bichromatic force scheme achieves 1.45e5 m/s2 deceleration on 13CO2 with negligible population loss by using long-lived vibrational states for coherent cycles.
Numerical simulations show that laser stirring parameters can be varied to deterministically nucleate stable infilled vortices with tunable high topological charge in an immiscible Rb-K BEC, which then exhibit charge-dependent precession and breathing modes.
Multi-parameter sudden-quench Otto cycles outperform single-parameter versions in net work, efficiency, and refrigerator coefficient of performance for a 1D Bose gas and Ising model.
Theory using dynamical high-temperature expansion and optical-lattice hard-core boson experiments show excellent agreement on spin diffusion constants in the finite-temperature square-lattice XY model.
Tuning charger frequency to resonance in a 1D bosonic quantum battery achieves perfect energy transfer, with many-body effects and attractive interactions enhancing charging power and efficiency over single-particle cases.
Simulations identify distinct regimes in 1D Bose-Josephson dynamics: coherent oscillations, imbalance-driven dephasing with collapse-revival, equilibration with fragmentation, and strong-interaction dynamical freezing with suppressed tunneling.
A two-channel model demonstrates stabilization of three-body resonances into bound states in the continuum via parameter tuning, shown in 1D mass-imbalanced and 3D Efimov systems with magnetic field control.
An educational exposition of Feshbach resonances in Li-6 using basic quantum mechanics to illustrate magnetic tuning of atomic interactions.
citing papers explorer
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Creation of ultracold heteronuclear p-wave Feshbach molecules
First creation of ultracold heteronuclear p-wave Feshbach molecules in a Na-Rb Bose-Bose mixture via magneto-association and resonance characterization.
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Temperature-Controlled Resonance in a Heteronuclear Quantum Gas Mixture
Temperature-controlled resonance arises in heteronuclear mixtures when thermal smearing reshapes the effective potential, shifting resonance position with temperature.
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Neural-network quantum states for solving few-body problems: application to Efimov physics
Neural network quantum states compute Efimov bound states for 3-6 boson systems and mass-imbalanced fermions at unitarity, matching known energies and reproducing scale invariance and wave function features.
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Coherent Molecular Deceleration via Vibrational Bichromatic Force
A vibrational bichromatic force scheme achieves 1.45e5 m/s2 deceleration on 13CO2 with negligible population loss by using long-lived vibrational states for coherent cycles.
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Deterministic Nucleation and Dynamics of Infilled Multiply-Charged Vortices in an Immiscible $^{87}\mathrm{Rb}$-$^{41}\mathrm{K}$ Mixture
Numerical simulations show that laser stirring parameters can be varied to deterministically nucleate stable infilled vortices with tunable high topological charge in an immiscible Rb-K BEC, which then exhibit charge-dependent precession and breathing modes.
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Enhanced performance of sudden-quench quantum Otto cycles via multi-parameter control
Multi-parameter sudden-quench Otto cycles outperform single-parameter versions in net work, efficiency, and refrigerator coefficient of performance for a 1D Bose gas and Ising model.
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Finite-temperature spin diffusion in the two-dimensional XY model
Theory using dynamical high-temperature expansion and optical-lattice hard-core boson experiments show excellent agreement on spin diffusion constants in the finite-temperature square-lattice XY model.
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Enhancing ultracold atomic batteries using tunable interactions
Tuning charger frequency to resonance in a 1D bosonic quantum battery achieves perfect energy transfer, with many-body effects and attractive interactions enhancing charging power and efficiency over single-particle cases.
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Dynamics of one-dimensional Bose-Josephson Junction in a Box Trap: From Coherent Oscillations to Many-Body Dephasing and Dynamical Freezing
Simulations identify distinct regimes in 1D Bose-Josephson dynamics: coherent oscillations, imbalance-driven dephasing with collapse-revival, equilibration with fragmentation, and strong-interaction dynamical freezing with suppressed tunneling.
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Stabilization of three-body resonances to bound states in a continuum
A two-channel model demonstrates stabilization of three-body resonances into bound states in the continuum via parameter tuning, shown in 1D mass-imbalanced and 3D Efimov systems with magnetic field control.
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Tuning Interatomic Forces with Magnetic Fields: Feshbach Resonances in Lithium-6
An educational exposition of Feshbach resonances in Li-6 using basic quantum mechanics to illustrate magnetic tuning of atomic interactions.
- Interaction-enabled metal-insulator phase transition in a driven quantum gas
- Phases and dynamics of an impurity immersed in one-dimensional quantum droplets