Your search keyword '"Steve Haupt"' showing total 4 results

1. Nonequilibrium thermodynamics and optimal cooling of a dilute atomic gas

Author

Daniel Mayer, Felix Schmidt, Steve Haupt, Quentin Bouton, Daniel Adam, Tobias Lausch, Eric Lutz, and Artur Widera

Subjects

Physics, QC1-999

Abstract

Characterizing and optimizing thermodynamic processes far from equilibrium is a challenge. This is especially true for nanoscopic systems made of a few particles. We here theoretically and experimentally investigate the nonequilibrium dynamics of a gas of a few noninteracting cesium atoms confined in a nonharmonic optical dipole trap and exposed to degenerate Raman sideband cooling pulses. We determine the axial phase-space distribution of the atoms after each Raman cooling pulse by tracing the evolution of the gas with position-resolved fluorescence imaging. We evaluate from it the entropy production and the statistical length between each cooling step. A single Raman pulse leads to a nonequilibrium state that does not thermalize on its own, due to the absence of interparticle collisions. Thermalization may be achieved by combining free phase-space evolution and trains of cooling pulses. We minimize the entropy production to a target thermal state to specify the optimal spacing between a sequence of equally spaced pulses and achieve in this way optimal thermalization. We finally use the statistical length to verify a refined version of the second law of thermodynamics. Altogether, these findings provide a general theoretical and experimental framework to analyze and optimize far-from-equilibrium processes of few-particle systems.

Published

2020

2. Nonequilibrium thermodynamics and optimal cooling of a dilute atomic gas

Author

Artur Widera, Steve Haupt, Daniel Mayer, Daniel Adam, Quentin Bouton, Tobias Lausch, Eric Lutz, and Felix Schmidt

Subjects

Physics, Statistical Mechanics (cond-mat.stat-mech), Entropy production, Quantum Gases (cond-mat.quant-gas), Atomic Physics (physics.atom-ph), Non-equilibrium thermodynamics, FOS: Physical sciences, Statistical physics, Physics::Atomic Physics, Condensed Matter - Quantum Gases, Measure (mathematics), Condensed Matter - Statistical Mechanics, Physics - Atomic Physics

Abstract

Characterizing and optimizing thermodynamic processes far from equilibrium is a challenge. This is especially true for nanoscopic systems made of few particles. We here theoretically and experimentally investigate the nonequilibrium dynamics of a gas of few noninteracting Cesium atoms confined in a nonharmonic optical dipole trap and exposed to degenerate Raman sideband cooling pulses. We determine the axial phase-space distribution of the atoms after each Raman cooling pulse by tracing the evolution of the gas with position-resolved fluorescence imaging. We evaluate from it the entropy production and the statistical length between each cooling steps. A single Raman pulse leads to a nonequilibrium state that does not thermalize on its own, due to the absence of interparticle collisions. Thermalization may be achieved by combining free phase-space evolution and trains of cooling pulses. We minimize the entropy production to a target thermal state to specify the optimal spacing between a sequence of equally spaced pulses and achieve in this way optimal thermalization. We finally use the statistical length to verify a refined version of the second law of thermodynamics. Altogether, these findings provide a general, theoretical and experimental, framework to analyze and optimize far-from-equilibrium processes of few-particle systems.

Published

2019

3. Controlled doping of a bosonic quantum gas with single neutral atoms

Author

Daniel Mayer, Tobias Lausch, Artur Widera, Steve Haupt, Daniel Adam, Jens Nettersheim, Felix Schmidt, Jennifer Koch, and Quentin Bouton

Subjects

Atomic Physics (physics.atom-ph), FOS: Physical sciences, 01 natural sciences, 010305 fluids & plasmas, law.invention, Physics - Atomic Physics, symbols.namesake, law, Impurity, Condensed Matter::Superconductivity, 0103 physical sciences, Physics::Atomic Physics, 010306 general physics, Physics, Condensed Matter::Quantum Gases, Optical lattice, Quantum Physics, Energetic neutral atom, Doping, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Elastic collision, Thermalisation, Quantum Gases (cond-mat.quant-gas), symbols, Condensed Matter::Strongly Correlated Electrons, Atomic physics, Raman spectroscopy, Condensed Matter - Quantum Gases, Quantum Physics (quant-ph), Bose–Einstein condensate

Abstract

We report on the experimental doping of a $^{87}$Rubidium (Rb) Bose-Einstein condensate (BEC) with individual neutral $^{133}$Cesium (Cs) atoms. We discuss the experimental tools and procedures to facilitate Cs-Rb interaction. First, we use degenerate Raman side-band cooling of the impurities to enhance the immersion efficiency for the impurity in the quantum gas. We identify the immersed fraction of Cs impurities from the thermalization of Cs atoms upon impinging on a BEC, where elastic collisions lead to a localization of Cs atoms in the Rb cloud. Second, further enhancement of the immersion probability is obtained by localizing the Cs atoms in a species-selective optical lattice and subsequent transport into the Rb cloud. Here, impurity-BEC interaction is monitored by position and time resolved three-body loss of Cs impurities immersed into the BEC. This combination of experimental methods allows for the controlled doping of a BEC with neutral impurity atoms, paving the way to impurity aided probing and coherent impurity-quantum bath interaction.

Published

2018

4. Controlled doping of a bosonic quantum gas with single neutral atoms.

Author

Daniel Mayer, Felix Schmidt, Daniel Adam, Steve Haupt, Jennifer Koch, Tobias Lausch, Jens Nettersheim, Quentin Bouton, and Artur Widera

Subjects

QUANTUM gases, RUBIDIUM, BOSE-Einstein condensation

Abstract

We report on the experimental doping of a 87Rubidium (Rb) Bose–Einstein condensate (BEC) with individual neutral 133Cesium (Cs) atoms. We discuss the experimental tools and procedures to facilitate Cs-Rb interaction. First, we use degenerate Raman side-band cooling of the impurities to enhance the immersion efficiency for the impurity in the quantum gas. We identify the immersed fraction of Cs impurities from the thermalization of Cs atoms upon impinging on a BEC, where elastic collisions lead to a localization of Cs atoms in the Rb cloud. Second, further enhancement of the immersion probability is obtained by localizing the Cs atoms in a species-selective optical lattice and a subsequent transport into the Rb cloud. Here, impurity-BEC interaction is monitored by position and time-resolved three-body loss of Cs impurities immersed into the BEC. This combination of experimental methods allows for the controlled doping of a BEC with neutral impurity atoms, paving the way to impurity aided probing and coherent impurity-quantum bath interaction. [ABSTRACT FROM AUTHOR]

Published

2019