New Paper: Physical Review Research

Kibble-Zurek scaling in quantum speed limits for shortcuts to adiabaticity

Ricardo Puebla, Sebastian Deffner, and Steve Campbell

Phys. Rev. Research 2, 032020(R) (2020)

Geometric quantum speed limits quantify the tradeoff between the rate at which quantum states can change and the resources that are expended during the evolution. Counterdiabatic driving is a unique tool from shortcuts to adiabaticity to speed up quantum dynamics while completely suppressing nonequilibrium excitations. We show that the quantum speed limit for counterdiabatically driven systems undergoing quantum phase transitions fully encodes the Kibble-Zurek mechanism by correctly predicting the transition from adiabatic to impulse regimes. Our findings are demonstrated for three scenarios, namely the transverse field Ising model, the Landau-Zener model, and the Lipkin-Meshkov-Glick model. ]]> Kibble-Zurek scaling in quantum speed limits for shortcuts to adiabaticity Ricardo Puebla, Sebastian Deffner, and Steve Campbell Phys. Rev. Research 2, 032020(R) (2020) Geometric quantum... https://journals.aps.org/prresearch/abstract/10.1103/PhysRevResearch.2.032020 https://beta.my.umbc.edu/api/v0/pixel/news/94503/guest@my.umbc.edu/1fe06e822c119425710bf48edd621ee2/api/pixel Quantum Thermodynamics https://beta.my.umbc.edu/groups/quthermo https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/original.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxlarge.png?1502988446 https://assets4-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xlarge.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/large.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/medium.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/small.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxsmall.png?1502988446 Quantum Thermodynamics 0 0 true Tue, 28 Jul 2020 10:56:00 -0400 New Paper: Journal of Nonequilibrium Thermodynamics

Endoreversible Otto Engines at Maximal Power

Zackary Smith, Priyo S. Pal, and Sebastian Deffner

DOI: 10.1515/jnet-2020-0039

Despite its idealizations, thermodynamics has proven its power as a predictive theory for practical applications. In particular, the Curzon–Ahlborn efficiency provides a benchmark for any real engine operating at maximal power. Here we further develop the analysis of endoreversible Otto engines. For a generic class of working mediums, whose internal energy is proportional to some power of the temperature, we find that no engine can achieve the Carnot efficiency at finite power. However, we also find that for the specific example of photonic engines the efficiency at maximal power is higher than the Curzon–Ahlborn efficiency.

J. Non-Equilib. Thermodyn. (published online ahead of print) (2020) ]]> Endoreversible Otto Engines at Maximal Power Zackary Smith, Priyo S. Pal, and Sebastian Deffner DOI: 10.1515/jnet-2020-0039 Despite its idealizations, thermodynamics has proven its power... https://beta.my.umbc.edu/api/v0/pixel/news/93533/guest@my.umbc.edu/f0e4e8c01b34c7b2e63d305a5ccc3981/api/pixel Quantum Thermodynamics https://beta.my.umbc.edu/groups/quthermo https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/original.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxlarge.png?1502988446 https://assets4-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xlarge.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/large.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/medium.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/small.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxsmall.png?1502988446 Quantum Thermodynamics 0 0 true Tue, 02 Jun 2020 04:24:25 -0400 Tue, 02 Jun 2020 04:25:56 -0400 Congratulations, Jacob and Alexandria! Undergraduate researchers, Jacob McCready and Alexandria Udenkwo, have both won the Undergraduate Research Award 2020. Congratulations! ]]> Undergraduate researchers, Jacob McCready and Alexandria Udenkwo, have both won the Undergraduate Research Award 2020. Congratulations! https://beta.my.umbc.edu/api/v0/pixel/news/93439/guest@my.umbc.edu/d427873819b291edc5d68c1738dfcc30/api/pixel Quantum Thermodynamics https://beta.my.umbc.edu/groups/quthermo https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/original.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxlarge.png?1502988446 https://assets4-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xlarge.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/large.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/medium.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/small.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxsmall.png?1502988446 Quantum Thermodynamics 0 0 true Wed, 27 May 2020 13:39:06 -0400 New Paper: Quantum Science and Technology

Quantum scrambling and the growth of mutual information


Akram Touil and Sebastian Deffner
Quantum Science and Technology, Volume 5, Number 3

Quantum information scrambling refers to the loss of local recoverability of quantum information, which has found widespread attention from high energy physics to quantum computing. In the present analysis we propose a possible starting point for the development of a comprehensive framework for the thermodynamics of scrambling. To this end, we prove that the growth of entanglement as quantified by the mutual information is lower bounded by the time-dependent change of out-of-time-ordered correlator. We further show that the rate of increase of the mutual information can be upper bounded by the sum of local entropy productions, and the exchange entropy arising from the flow of information between separate partitions of a quantum system. Our results are illustrated for the ion trap system, that was recently used to verify information scrambling in an experiment, and for the Sachdev–Ye–Kitaev model.

]]> Quantum scrambling and the growth of mutual information Akram Touil and Sebastian Deffner Quantum Science and Technology, Volume 5, Number 3 Quantum information scrambling refers to the... https://iopscience.iop.org/article/10.1088/2058-9565/ab8ebb https://beta.my.umbc.edu/api/v0/pixel/news/93409/guest@my.umbc.edu/ab679e03f447a4bde383c3d2ddeca13a/api/pixel Quantum Thermodynamics https://beta.my.umbc.edu/groups/quthermo https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/original.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxlarge.png?1502988446 https://assets4-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xlarge.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/large.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/medium.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/small.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxsmall.png?1502988446 Quantum Thermodynamics 0 0 true Tue, 26 May 2020 11:03:35 -0400 New Paper: Physical Review Letters Phys. Rev. Lett. 124, 110601 (2020)

Orthogonality Catastrophe as a Consequence of the Quantum Speed Limit

Thomás Fogarty, Sebastian Deffner, Thomas Busch, and Steve Campbell
Phys. Rev. Lett. 124, 110601 (2020)
A remarkable feature of quantum many-body systems is the orthogonality catastrophe that describes their extensively growing sensitivity to local perturbations and plays an important role in condensed matter physics. Here we show that the dynamics of the orthogonality catastrophe can be fully characterized by the quantum speed limit and, more specifically, that any quenched quantum many-body system, whose variance in ground state energy scales with the system size, exhibits the orthogonality catastrophe. Our rigorous findings are demonstrated by two paradigmatic classes of many-body systems—the trapped Fermi gas and the long-range interacting Lipkin-Meshkov-Glick spin model. ]]> Orthogonality Catastrophe as a Consequence of the Quantum Speed Limit Thomás Fogarty, Sebastian Deffner, Thomas Busch, and Steve Campbell Phys. Rev. Lett. 124, 110601 (2020) A remarkable... https://beta.my.umbc.edu/api/v0/pixel/news/91361/guest@my.umbc.edu/270da17f773b48b2d9bfb6b91d796774/api/pixel Quantum Thermodynamics https://beta.my.umbc.edu/groups/quthermo https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/original.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxlarge.png?1502988446 https://assets4-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xlarge.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/large.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/medium.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/small.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxsmall.png?1502988446 Quantum Thermodynamics 0 0 true Mon, 16 Mar 2020 11:51:06 -0400 Congratulations: Jacob McCready Donald N. Langenberg Undergraduate Research Award in Physics Jacob has been awarded the 2020-2021 Donald N. Langenberg Undergraduate Research Award in Physics to assist in his studies of particle interactions with regards to quantum thermodynamic applications. This year the award carries a stipend of $900.

Congratulations!
]]> Jacob has been awarded the 2020-2021 Donald N. Langenberg Undergraduate Research Award in Physics to assist in his studies of particle interactions with regards to quantum thermodynamic... https://beta.my.umbc.edu/api/v0/pixel/news/90893/guest@my.umbc.edu/870187d6bfb28f968fa5f0be6b15c7b5/api/pixel Quantum Thermodynamics https://beta.my.umbc.edu/groups/quthermo https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/original.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxlarge.png?1502988446 https://assets4-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xlarge.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/large.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/medium.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/small.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxsmall.png?1502988446 Quantum Thermodynamics 0 0 true Mon, 02 Mar 2020 09:50:44 -0500 Special Issue: "Thermodynamics of Quantum Information" Our Special Issue on "Thermodynamics of Quantum Information" in Entropy is now open for submissions!! Looking forward to all the great papers: ]]> Our Special Issue on "Thermodynamics of Quantum Information" in Entropy is now open for submissions!! Looking forward to all the great papers: https://beta.my.umbc.edu/api/v0/pixel/news/90478/guest@my.umbc.edu/edeb26235275d521181f29be11cb4312/api/pixel Quantum Thermodynamics https://beta.my.umbc.edu/groups/quthermo https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/original.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxlarge.png?1502988446 https://assets4-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xlarge.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/large.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/medium.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/small.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxsmall.png?1502988446 Quantum Thermodynamics 0 0 true Fri, 14 Feb 2020 17:24:27 -0500 New Paper: Physical Review Research

Quantum speed limits and the maximal rate of information production

Phys. Rev. Research 2, 013161 (2020)

The Bremermann-Bekenstein bound sets a fundamental upper limit on the rate with which information can be processed. However, the original treatment heavily relies on cosmological properties and plausibility arguments. In the present analysis, we derive equivalent statements by relying on only two fundamental results in quantum information theory and quantum dynamics: the Fannes inequality and the quantum speed limit. As main results, we obtain Bremermann-Bekenstein-type bounds for the rate of change of the von Neumann entropy in quantum systems undergoing open system dynamics and for the rate of change of the Shannon information encoded in some logical states undergoing unitary quantum evolution. ]]> Quantum speed limits and the maximal rate of information production Phys. Rev. Research 2, 013161 (2020) The Bremermann-Bekenstein bound sets a fundamental upper limit on the rate with which... https://beta.my.umbc.edu/api/v0/pixel/news/90459/guest@my.umbc.edu/4e052de6a1840af7e549e8fdae5cd696/api/pixel Quantum Thermodynamics https://beta.my.umbc.edu/groups/quthermo https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/original.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxlarge.png?1502988446 https://assets4-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xlarge.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/large.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/medium.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/small.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxsmall.png?1502988446 Quantum Thermodynamics 0 0 true Fri, 14 Feb 2020 10:34:55 -0500 Fri, 14 Feb 2020 10:35:53 -0500 New paper: Journal of Statistical Mechanics Compatibility of linear-response theory with the second law Pierre Nazé and Marcus V. S. Bonança
J. Stat. Mech. (2020) 013206

The reliability of physical theories depends on whether they agree with well-established physical laws. In this work, we address the compatibility of the Hamiltonian formulation of linear-response theory with the second law of thermodynamics. In order to do so, we verify three complementary aspects often understood as statements of the second law: (1) no dissipation for quasistatic process; (2) dissipation for finite-time processes; and (3) positive entropy production rate. Our analysis focuses on two classes of nonequilibrium isothermal processes: slowly-varying and finite-time but weak ones. For the former, we show that these aspects are easily verified. For the later, we present conditions for the achievement of the first two aspects. We also show that the third one is not always verified, presenting an example based on Brownian motion in which we observe negative values in the entropy production rate. In particular, we compare linear-response and exact results for this example.
]]> Pierre Nazé and Marcus V. S. Bonança J. Stat. Mech. (2020) 013206 The reliability of physical theories depends on whether they agree with well-established physical laws. In this work, we... https://iopscience.iop.org/article/10.1088/1742-5468/ab54ba https://beta.my.umbc.edu/api/v0/pixel/news/89643/guest@my.umbc.edu/4f2a228e893f6aa98687120d6fad3f1a/api/pixel Quantum Thermodynamics https://beta.my.umbc.edu/groups/quthermo https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/original.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxlarge.png?1502988446 https://assets4-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xlarge.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/large.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/medium.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/small.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxsmall.png?1502988446 Quantum Thermodynamics 0 0 true Wed, 15 Jan 2020 08:54:29 -0500 New Paper: Physical Review E Bosons outperform fermions

Bosons outperform fermions: The thermodynamic advantage of symmetry


Nathan M. Myers and Sebastian Deffner
Phys. Rev. E 101, 012110 (2020)

We examine a quantum Otto engine with a harmonic working medium consisting of two particles to explore the use of wave function symmetry as an accessible resource. It is shown that the bosonic system displays enhanced performance when compared to two independent single particle engines, while the fermionic system displays reduced performance. To this end, we explore the trade-off between efficiency and power output and the parameter regimes under which the system functions as engine, refrigerator, or heater. Remarkably, the bosonic system operates under a wider parameter space both when operating as an engine and as a refrigerator.
]]> Bosons outperform fermions: The thermodynamic advantage of symmetry Nathan M. Myers and Sebastian Deffner Phys. Rev. E 101, 012110 (2020) We examine a quantum Otto engine with a... https://journals.aps.org/pre/abstract/10.1103/PhysRevE.101.012110 https://beta.my.umbc.edu/api/v0/pixel/news/89501/guest@my.umbc.edu/f93b77e40a15c98075a1c5fd703aee74/api/pixel Quantum Thermodynamics https://beta.my.umbc.edu/groups/quthermo https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/original.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxlarge.png?1502988446 https://assets4-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xlarge.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/large.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/medium.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/small.png?1502988446 https://assets1-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xsmall.png?1502988446 https://assets3-beta.my.umbc.edu/system/shared/avatars/groups/000/001/393/cfed54c41318d9b704a1ec1b884218b1/xxsmall.png?1502988446 Quantum Thermodynamics 0 0 true Wed, 08 Jan 2020 14:46:37 -0500 Wed, 08 Jan 2020 15:39:21 -0500