Quantum Joule-Thomson Effect in a Saturated Homogeneous Bose Gas

Schmidutz, Tobias F.; Gotlibovych, Igor; Gaunt, Alexander L.; Smith, Robert P.; Navon, Nir; Hadzibabic, Zoran

doi:10.1103/physrevlett.112.040403

Cited by 51 publications

(61 citation statements)

References 34 publications

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“…This competition can lead to an increase in condensate fraction, because BEC atoms have zero energy. Hence, melting of the BEC cools the thermal gas in m min s , which can then be saturated at a lower temperature, as already observed in [20] and [21].…”

supporting

confidence: 60%

Cooling of a Bose-Einstein Condensate by Spin Distillation

Naylor¹,

Maréchal²,

Huckans³

et al. 2015

Phys. Rev. Lett.

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We propose and experimentally demonstrate a new cooling mechanism leading to purification of a spinor Bose-Einstein Condensate (BEC). Our scheme starts with a BEC polarized in the lowest energy spin state. Spin excited states are thermally populated by lowering the single particle energy gap set by the magnetic field. Then these spin-excited thermal components are filtered out, which leads to an increase of the BEC fraction. We experimentally demonstrate such cooling for a spin 3 52 Cr dipolar BEC. Our scheme should be applicable to Na or Rb, with perspective to reach temperatures below 1 nK.PACS numbers: 37.10. De, 03.75.Mn,75.30.Sg In the last three decades, laser cooling and evaporative cooling have led to major advances in atomic and molecular physics, in particular in the fields of precision measurements, atomic clocks, and quantum degenerate gases [1,2]. Nowadays, the hope to study magnetic correlations of atoms in optical lattices [3,4], and the possible connections to exotic superconductivity are major motivations to obtain systems with lower entropies than currently available [5]. It is therefore important to find new ways to remove entropy in degenerate quantum Bose or Fermi gases loaded in optical lattices [6][7][8][9].In typical lattice experiments, atoms are first cooled by evaporative cooling, and then loaded in the periodic potential. Unfortunately, evaporative cooling ceases to be efficient when the temperature is significantly smaller than the interaction energy, which currently sets an ultimate limit for entropy [10]. A number of alternative cooling schemes have been suggested and studied [11][12][13][14][15][16] but up to now the best phase space densities are still due to evaporative cooling. Here, we propose to use the spin degrees of freedom to efficiently store and remove entropy in partially Bose-condensed gases to reach temperatures below the current limitations set by evaporative cooling.Our proposal starts with a sample polarized in the lowest energy spin state. We engineer a thermodynamic cycle (see fig. 1a)) wherein the magnetic field is first lowered to trigger depolarization of the gas, and the resultant spin-excited states are then filtered out of the trap. As shown in fig. 1c), this cycle reproduces a BEC polarized in the lowest energy state with an increased condensate fraction, provided the initial thermal fraction is low enough. The gain in phase space density directly follows from Bose statistics: as the condensate forms in the lowest energy single-particle spin state [17], spin filtering of the excited spin states obtained after depolarization introduces a loss which is specific to thermal atoms. At low magnetic field, spin filtering typically leads to a decrease of the thermal fraction, and hence of entropy, by a factor 52 Cr BEC forming only in ms = −3. Circles are experimental data, the solid line is result of bimodal fit, and the dashed line only fits thermal fractions. c) Purification of a 52 Cr BEC. After depolarization occurring at a B field of 1 mG, we measure the...

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supporting

confidence: 60%

Cooling of a Bose-Einstein Condensate by Spin Distillation

Naylor¹,

Maréchal²,

Huckans³

et al. 2015

Phys. Rev. Lett.

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“…4). This is an extreme manifestation of the Joule Thompson effect in the quantum regime [24], where the interaction energy is converted into thermal energy. For larger filling, the atoms condense, and the width of the density distribution gets smaller.…”

mentioning

confidence: 99%

Negative Differential Conductivity in an Interacting Quantum Gas

et al. 2015

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We report on the observation of negative differential conductivity (NDC) in a quantum transport device for neutral atoms employing a multimode tunneling junction. The system is realized with a Bose-Einstein condensate loaded in a one-dimensional optical lattice with high site occupancy. We induce an initial difference in chemical potential at one site by local atom removal. The ensuing transport dynamics are governed by the interplay between the tunneling coupling, the interaction energy, and intrinsic collisions, which turn the coherent coupling into a hopping process. The resulting current-voltage characteristics exhibit NDC, for which we identify atom number-dependent tunneling as a new microscopic mechanism. Our study opens new ways for the future implementation and control of complex neutral atom quantum circuits.

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“…This is most severe for supersolid states, such as the elusive FFLO state [21][22][23], where the emergent spatial period is well defined only in a homogeneous setting. A natural solution to these problems is the use of uniform potentials, which have recently proved to be advantageous for thermodynamic and coherence measurements with Bose gases [24][25][26][27].…”

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confidence: 99%

Homogeneous Atomic Fermi Gases

et al. 2017

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We report on the creation of homogeneous Fermi gases of ultracold atoms in a uniform potential. In the momentum distribution of a spin-polarized gas, we observe the emergence of the Fermi surface and the saturated occupation of one particle per momentum state: the striking consequence of Pauli blocking in momentum space for a degenerate gas. Cooling a spin-balanced Fermi gas at unitarity, we create homogeneous superfluids and observe spatially uniform pair condensates. For thermodynamic measurements, we introduce a hybrid potential that is harmonic in one dimension and uniform in the other two. The spatially resolved compressibility reveals the superfluid transition in a spin-balanced Fermi gas, saturation in a fully polarized Fermi gas, and strong attraction in the polaronic regime of a partially polarized Fermi gas.

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Quantum Joule-Thomson Effect in a Saturated Homogeneous Bose Gas

Cited by 51 publications

References 34 publications

Cooling of a Bose-Einstein Condensate by Spin Distillation

Cooling of a Bose-Einstein Condensate by Spin Distillation

Negative Differential Conductivity in an Interacting Quantum Gas

Homogeneous Atomic Fermi Gases

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