Two-Point Phase Correlations of a One-Dimensional Bosonic Josephson Junction

Betz, Thomas; Manz, Stephanie; Bücker, Robert; Berrada, Tarik; Koller, Ch.; Kazakov, G.; Mazets, I. E.; Stimming, Hans Peter; Perrin, Aurélien; Schumm, Thorsten; Schmiedmayer, Jörg

doi:10.1103/physrevlett.106.020407

Cited by 93 publications

(125 citation statements)

References 28 publications

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“…1) [21]. Matter-wave interferometry [22][23][24] gives direct access to the spatially resolved relative phase ϕ(z) between the superfluids (see Methods).…”

Section: Arxiv:150503126v2 [Cond-matquant-gas] 19 May 2017mentioning

confidence: 99%

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Experimental characterization of a quantum many-body system via higher-order correlations

Schweigler

Kasper

Erne

et al. 2017

Nature

241

319

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“…1) [21]. Matter-wave interferometry [22][23][24] gives direct access to the spatially resolved relative phase ϕ(z) between the superfluids (see Methods).…”

Section: Arxiv:150503126v2 [Cond-matquant-gas] 19 May 2017mentioning

confidence: 99%

“…The strength of this 'phase locking' is characterised by cos(ϕ) , a quantity that is zero for completely random phases (no phase locking) and approaches unity in the limit of strong phase locking. The value of cos(ϕ) depends on the tunnelcoupling strength as well as on the temperature [21].…”

Section: Arxiv:150503126v2 [Cond-matquant-gas] 19 May 2017mentioning

confidence: 99%

Experimental characterization of a quantum many-body system via higher-order correlations

Schweigler

Kasper

Erne

et al. 2017

Nature

241

319

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“…In the case of two uncoupled quasicondensates in thermal equilibrium with temperature T, the thermal phase-correlation length is given by ¼ @ 2 =mk B T [30,31]. Due to our rapid splitting process, the energy initially stored in the system is equally distributed between the different k modes of the system [12,14], resulting in thermal-like correlations characterized by an effective temperature k B T eff ¼ hĤij t¼0 ¼ g=2.…”

Section: Fig 4 (Color)mentioning

confidence: 99%

Multimode Dynamics and Emergence of a Characteristic Length Scale in a One-Dimensional Quantum System

et al. 2013

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We study the nonequilibrium dynamics of a coherently split one-dimensional Bose gas by measuring the full probability distribution functions of matter-wave interference. Observing the system on different length scales allows us to probe the dynamics of excitations on different energy scales, revealing two distinct length-scale-dependent regimes of relaxation. We measure the crossover length scale separating these two regimes and identify it with the prethermalized phase-correlation length of the system. Our approach enables a direct observation of the multimode dynamics characterizing one-dimensional quantum systems. The nonequilibrium dynamics of many-body quantum systems and their pathway towards equilibrium is of fundamental importance in vastly different fields of physics. Open questions appear, for example, in high-energy physics for understanding quark-gluon plasma [1][2][3], in cosmology for describing preheating of the early Universe [4], or in the comprehension of relaxation processes in condensed-matter systems [5,6].Because of their isolation from the environment and their tunability, ultracold atom systems have triggered many studies of nonequilibrium dynamics in closed interacting quantum systems, with particular interest drawn to quantum quenches [7,8]. Important questions are related to systems where the dynamics is constrained by several constants of motion [9] and to the possible description of nonequilibrium states by generalized statistical mechanics ensembles [10,11].Recently, we reported the experimental observation of prethermalization in a coherently split one-dimensional (1D) ultracold Bose gas [12], made possible by a characterization of the dynamical states through measurements of full distribution functions [13,14]. Prethermalization [15] was understood as the rapid relaxation to a steady state exhibiting thermal-like properties but differing from the true thermal equilibrium that is eventually expected to occur on longer time scales [16][17][18][19][20].In this Letter, we study the relaxation process [21] leading to the prethermalized state by measuring the full (probability) distribution functions (FDFs) of phase and contrast of matter-wave interference. We probe the 1D system on different length scales to investigate its multimode dynamics, which reveals two distinct regimes separated by a characteristic crossover length scale. We measure this characteristic length scale and identify it with the effective thermal phase-correlation length of the prethermalized system.We prepare a quasi-1D Bose gas of several thousand 87 Rb atoms in an elongated (along the z direction) magnetic microtrap on an atom chip [22] at a (tunable) temperature between 20 and 120 nK. The gas is coherently split along the radial (x) direction using a symmetric radio-frequency dressed-state double-well potential [23], creating two uncoupled 1D gases separated by a distance of 3:1 m [ Fig. 1(a)]. The longitudinal and radial trap frequencies in the double well are 7 Hz and 1.4 kHz, respectively, and the size of the...

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“…Such systems offer a new tool to study quantum coherence in various contexts [9,25,27,30]. For instance, measurement of the relative-phase correlation function of a coupled binary Bose gas in one dimension was reported in Ref.…”

Section: Introductionmentioning

confidence: 99%

“…Early studies focused on the possibility of observing Bose-Einstein condensation [11], as well as stability conditions [1,12,13], phase separation [8,[14][15][16][17][18][19][20], and spontaneous symmetry breaking mechanisms [21][22][23][24] in twocomponent Bose-Einstein condensates. Two-component Bose gases have also been used to study phase coherence [25], Josephson like physics [26][27][28][29][30], the dynamics of spin textures [31][32][33][34], random-field-induced order effects [35,36], and twin quantum states for quantum information processing [37][38][39].…”

Section: Introductionmentioning

confidence: 99%

Two-component Bose gases with one-body and two-body couplings

et al. 2013

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We study the competition between one-body and two-body couplings in weakly-interacting twocomponent Bose gases, in particular as regards field correlations. We derive the meanfield theory for both ground state and low-energy pair excitations in the general case where both one-body and two-body couplings are position-dependent and the fluid is subjected to a state-dependent trapping potential. General formulas for phase and density correlations are also derived. Focusing on the case of homogeneous systems, we discuss the pair-excitation spectrum and the corresponding excitation modes, and use them to calculate correlation functions, including both quantum and thermal fluctuation terms. We show that the relative phase of the two components is imposed by that of the one-body coupling, while its fluctuations are determined by the modulus of the one-body coupling and by the two-body coupling. One-body coupling and repulsive two-body coupling cooperate to suppress relative-phase fluctuations, while attractive two-body coupling tends to enhance them. Further applications of the formalism presented here and extensions of our work are also discussed.

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Two-Point Phase Correlations of a One-Dimensional Bosonic Josephson Junction

Cited by 93 publications

References 28 publications

Experimental characterization of a quantum many-body system via higher-order correlations

Experimental characterization of a quantum many-body system via higher-order correlations

Multimode Dynamics and Emergence of a Characteristic Length Scale in a One-Dimensional Quantum System

Two-component Bose gases with one-body and two-body couplings

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