Experimental test of the quantum Jarzynski equality with a trapped-ion system

An, Shuoming; Zhang, Jingning; Um, Mark; Lv, Dingshun; Lu, Yao; Zhang, Junhua; Yin, Zhang‐qi; Quan, H. T.; Kim, Kihwan

doi:10.1038/nphys3197

Cited by 355 publications

(364 citation statements)

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“…This research direction invokes a crucial assumption that the heat bath is, at least in the initial time, in the canonical distribution [48]; this special initial condition effectively breaks the time-reversal symmetry and leads to the second law of thermodynamics. The same assumption has been employed in various modern researches on thermodynamics, such as the nonequilibrium fluctuation theorem [48][49][50][51][52][53][54][55][56][57][58] and the thermodynamic resource theory [59,60].…”

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confidence: 99%

Fluctuation Theorem for Many-Body Pure Quantum States

2017

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We prove the second law of thermodynamics and the nonequilibirum fluctuation theorem for pure quantum states. The entire system obeys reversible unitary dynamics, where the initial state of the heat bath is not the canonical distribution but is a single energy-eigenstate that satisfies the eigenstatethermalization hypothesis (ETH). Our result is mathematically rigorous and based on the Lieb-Robinson bound, which gives the upper bound of the velocity of information propagation in many-body quantum systems. The entanglement entropy of a subsystem is shown connected to thermodynamic heat, highlighting the foundation of the information-thermodynamics link. We confirmed our theory by numerical simulation of hard-core bosons, and observed dynamical crossover from thermal fluctuations to bare quantum fluctuations. Our result reveals a universal scenario that the second law emerges from quantum mechanics, and can experimentally be tested by artificial isolated quantum systems such as ultracold atoms.Introduction. Although the microscopic laws of physics do not prefer a particular direction of time, the macroscopic world exhibits inevitable irreversibility represented by the second law of thermodynamics. Modern researches has revealed that even a pure quantum state, described by a single wave function without any genuine thermal fluctuation, can relax to macroscopic thermal equilibrium by a reversible unitary evolution [1][2][3][4][5][6][7][8][9][10][11]. Thermalization of isolated quantum systems, which is relevant to the zeroth law of thermodynamics, is now a very active area of researches in theory [1-6], numerics [10][11][12][13][14][15][16], and experiments [17][18][19][20][21][22][23]. Especially, the concepts of typicality [9,[24][25][26] and the eigenstate thermalization hypothesis (ETH) [10][11][12][27][28][29][30][31][32][33][34][35][36] have played significant roles.However, the second law of thermodynamics, which states that the thermodynamic entropy increases in isolated systems, has not been fully addressed in this context. We would emphasize that the informational entropy (i.e., the von Neumann entropy) of such a genuine quantum system never increases, but is always zero [37]. In this sense, a fundamental gap between the microscopic and macroscopic worlds has not yet been bridged: How does the second law emerge from pure quantum states?In a rather different context, a general theory of the second law and its connection to information has recently been developed even out of equilibrium [38][39][40][41], which has also been experimentally verified in laboratories [42][43][44][45]. This has revealed that information contents and thermodynamic quantities can be treated on an equal footing, as originally illustrated by Szilard and Landauer in the context of Maxwell's demon [46,47]. This research direction invokes a crucial assumption that the heat bath is, at least in the initial time, in the canonical distribution [48]; this special initial condition effectively breaks the

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confidence: 99%

Fluctuation Theorem for Many-Body Pure Quantum States

2017

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“…Moreover, a direct evidence of the profile P(W) by experiments reports the distinct non-Gaussian work distribution [7], where the motion of an overdamped colloidal particle in a time-dependent nonharmonic potential was traced. Also in quantum regime, the observed work distribution in a trapped ion system is found to be different from the Gaussian form [8].…”

Section: Introductionmentioning

confidence: 98%

A Lower Bound on Work Extraction Probability Prescribed by Nonequilibrium Work Relation

Yamano

2017

The 4th International Electronic Conference on Entropy and Its Applications

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Abstract:In nonequilibrium processes, work extraction from a system is subject to random fluctuations associated with the statistical distribution prescribed by its environment. The probability of extracting work above a given arbitrary threshold can be a measure of restriction imposed by experimental circumstances. We present a lower bound for the probability when the work value lies in a finite range. For the case of fixed maximum work, the lower bound gets larger as the free energy difference between initial and final states becomes larger. We point out also that an upper bound previously reported in the literature is a direct consequence of the well-known second mean value theorem for definite integrals.

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“…In trapped-ion experiments, RAPs have been used for electronic-state manipulation [43,44] and for Fock-state measurements with a single ion [45] by multiple RAPs. For an ion string, a RAP on a red-sideband transition enables conversion of phononic into electronic excitations if the laser pulse is globally applied to all the ions in a crystal that is initially prepared in the electronic ground state.…”

Section: A Eit Cooling Of Multi-ion Crystalsmentioning

confidence: 99%

Electromagnetically-induced-transparency ground-state cooling of long ion strings

et al. 2016

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Electromagnetically-induced-transparency (EIT) cooling is a ground-state cooling technique for trapped particles. EIT offers a broader cooling range in frequency space compared to more established methods. In this work, we experimentally investigate EIT cooling in strings of trapped atomic ions. In strings of up to 18 ions, we demonstrate simultaneous ground state cooling of all radial modes in under 1 ms. This is a particularly important capability in view of emerging quantum simulation experiments with large numbers of trapped ions. Our analysis of the EIT cooling dynamics is based on a novel technique enabling single-shot measurements of phonon numbers, by rapid adiabatic passage on a vibrational sideband of a narrow transition.

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Experimental test of the quantum Jarzynski equality with a trapped-ion system

Cited by 355 publications

References 52 publications

Fluctuation Theorem for Many-Body Pure Quantum States

Fluctuation Theorem for Many-Body Pure Quantum States

A Lower Bound on Work Extraction Probability Prescribed by Nonequilibrium Work Relation

Electromagnetically-induced-transparency ground-state cooling of long ion strings

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