Thermometry and cooling of a Bose gas to 0.02 times the condensation temperature

Olf, Ryan; Fang, Fang; Marti, G. Edward; MacRae, Andrew; Stamper-Kurn, Dan

doi:10.1038/nphys3408

Cited by 75 publications

(83 citation statements)

References 27 publications

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“…Previous experimental works exploring finite temperatures in spinor gases mostly studied spin dynamics in thermal gases [23][24][25][26], or demonstrated cooling of a majority Zeeman component by selective evaporation of the minority components [27,28]. The realization of dipolar spinor gases with free magnetization [15] was limited to the study of spin-polarized condensed phases in equilibrium due to dipolar relaxation.…”

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confidence: 99%

Stepwise Bose-Einstein Condensation in a Spinor Gas

et al. 2017

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We observe multi-step condensation of sodium atoms with spin F = 1, where the different Zeeman components mF = 0, ±1 condense sequentially as the temperature decreases. The precise sequence changes drastically depending on the magnetization mz and on the quadratic Zeeman energy q (QZE) in an applied magnetic field. For large QZE, the overall structure of the phase diagram is the same as for an ideal spin 1 gas, although the precise locations of the phase boundaries are significantly shifted by interactions. For small QZE, antiferromagnetic interactions qualitatively change the phase diagram with respect to the ideal case, leading for instance to condensation in mF = ±1, a phenomenon that cannot occur for an ideal gas with q > 0.Multi-component quantum fluids described by a vector or tensor order parameter are often richer than their scalar counterparts. Examples in condensed matter are superfluid 3 He [1] or some unconventional superconductors with spin-triplet Cooper pairing [2]. In atomic physics, spinor Bose-Einstein condensates (BEC) with several Zeeman components m F inside a given hyperfine spin F manifold can display non-trivial spin order at low temperatures [3][4][5][6]. The macroscopic population of the condensate enhances the role of small energy scales that are negligible for normal gases. This mechanism (sometimes termed Bose-enhanced magnetism [6]) highlights the deep connection between Bose-Einstein condensation and magnetism in bosonic gases, and raises the question of the stability of spin order against temperature.In simple cases, magnetic order appears as soon as a BEC forms. Siggia and Ruckenstein [7] pointed out for two-component BECs [7] that a well-defined relative phase between the two components implies a macroscopic transverse spin. BEC and ferromagnetism then occur simultaneously, provided the relative populations can adjust freely. A recent experiment confirmed this scenario for bosons with spin-orbit coupling [8]. This conclusion was later generalized to spin-F bosons without [9] or with spin-independent [10] interactions. These results indicate that without additional constraints, bosonic statistics favors ferromagnetism.In atomic quantum gases with F > 1/2, this type of ferromagnetism competes with spin-exchange interactions, which may favor other spin orders such as spinnematics [6]. Spin-exchange collisions can redistribute populations among the Zeeman states [11][12][13], but are also invariant under spin rotations. The allowed redistribution processes are therefore those preserving the total spin, such as 2 × (m F = 0) ↔ (m F = +1) + (m F = −1). For an isolated system driven to equilibrium only by binary collisions (in contrast with solid-state magnetic materials [14]), and where magnetic dipole-dipole interactions are negligible (in contrast with dipolar atoms [15]), the longitudinal magnetization m z is then a conserved quantity. This conservation law has deep consequences on the thermodynamic phase diagram.The thermodynamics of spinor gases with conserved magnetization has b...

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Stepwise Bose-Einstein Condensation in a Spinor Gas

et al. 2017

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“…Thus, it is important to determine and investigate the entropy-temperature curves [32]. The behavior of these curves is used in analyzing the process of adiabatic cooling [19,33,34]. For the rotating condensate in an optical lattice, the normalized entropy per particle is given by Blakie [32] (25)…”

Section: Entropy Of the Systemmentioning

confidence: 99%

“…Following our procedure illustrated in our previous work [8] we have, (18) with = (19) and is the BEC transition temperature of a harmonically trapped nonrotating atoms. The parameter in Eq.…”

Section: Condensate Density and Chemical Potentialmentioning

confidence: 99%

“…Many open questions related to exploring the effects of interatomic interactions, rotation rate and optical potential depth on the behavior of this system under different circumstances [14] are considered. These include: the BEC transition temperature [15,16]; the heat capacity, which enabled us to discuss the order of phase transition [17,18] and the entropy of the system [19], required to investigate the adiabatic cooling of the boson system in lattice. Our results are given for the trap parameters of the Hadzibabic's et al experiment [13]: the radial and axial frequencies of the harmonic trap are I N THIS work, we investigated the thermodynamic behavior of a rotating Bose-Einstein condensation with non-zero interatomic interactions in one-dimensional optical lattice theoretically.…”

Section: Introductionmentioning

confidence: 99%

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Hartree-Fock Approach for Rotating Bose-Einstein Condensation in One-dimensional Deep Optical Lattice

2017

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“…We therefore choose to extract temperature information from the y−dimension, where the resulting momentum distribution of the condensate fraction is narrower, and apply a temperature cut-off at T ≤ 0.3T c . An investigation of the very low temperature region (T < 0.3T c ) would require a new thermometry technique to be used, such as recently presented by Olf et al This technique involves analyzing the decoherence of a quantum superposition of spin states, which allows them to measure temperatures as low as 0.02T c [16].…”

Section: B)mentioning

confidence: 99%

Calorimetry of a harmonically trapped Bose gas

et al. 2015

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We experimentally study the energy-temperature relationship of a harmonically trapped BoseEinstein condensate by transferring a known quantity of energy to the condensate and measuring the resulting temperature change. We consider two methods of heat transfer, the first using a free expansion under gravity and the second using an optical standing wave to diffract the atoms in the potential. We investigate the effect of interactions on the thermodynamics and compare our results to various finite temperature theories.

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Thermometry and cooling of a Bose gas to 0.02 times the condensation temperature

Cited by 75 publications

References 27 publications

Stepwise Bose-Einstein Condensation in a Spinor Gas

Stepwise Bose-Einstein Condensation in a Spinor Gas

Hartree-Fock Approach for Rotating Bose-Einstein Condensation in One-dimensional Deep Optical Lattice

Calorimetry of a harmonically trapped Bose gas

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