Elementary Thermal Operations

To what extent do thermodynamic resource theories capture physically relevant constraints? Inspired by quantum computation, we define a set of elementary thermodynamic gates that only act on 2 energy levels of a system at a time. We show that this theory is well reproduced by a Jaynes-Cummings interaction in rotating wave approximation and draw a connection to standard descriptions of thermalisation. We then prove that elementary thermal operations present tighter constraints on the allowed transformations than thermal operations. Mathematically, this illustrates the failure at finite temperature of fundamental theorems by Birkhoff and Muirhead-Hardy-Littlewood-Polya concerning stochastic maps. Physically, this implies that stronger constraints than those imposed by single-shot quantities can be given if we tailor a thermodynamic resource theory to the relevant experimental scenario. We provide new tools to do so, including necessary and sufficient conditions for a given change of the population to be possible. As an example, we describe the resource theory of the Jaynes-Cummings model. Finally, we initiate an investigation into how our resource theories can be applied to Heat Bath Algorithmic Cooling protocols.

[1]  R. Renner,et al.  A measure of majorization emerging from single-shot statistical mechanics , 2012, 1207.0434.

[2]  R. Spekkens,et al.  Modes of asymmetry: The application of harmonic analysis to symmetric quantum dynamics and quantum reference frames , 2013, 1312.0680.

[3]  A. J. Short,et al.  Work extraction and thermodynamics for individual quantum systems , 2013, Nature Communications.

[4]  David Jennings,et al.  Description of quantum coherence in thermodynamic processes requires constraints beyond free energy , 2014, Nature Communications.

[5]  I. Olkin,et al.  Inequalities: Theory of Majorization and Its Applications , 1980 .

[6]  Mário Ziman,et al.  Description of Quantum Dynamics of Open Systems Based on Collision-Like Models , 2004, Open Syst. Inf. Dyn..

[7]  The low density limit for anN-level system interacting with a free bose or fermi gas , 1985 .

[8]  D. O’Regan,et al.  Hardy and Littlewood Type Inequalities , 2016 .

[9]  Jonathan Oppenheim,et al.  Fluctuating States: What is the Probability of a Thermodynamical Transition? , 2015, 1504.00020.

[10]  J. Åberg Truly work-like work extraction via a single-shot analysis , 2011, Nature Communications.

[11]  Ronnie Kosloff,et al.  Quantum Thermodynamics: A Dynamical Viewpoint , 2013, Entropy.

[12]  R. Muirhead Some Methods applicable to Identities and Inequalities of Symmetric Algebraic Functions of n Letters , 1902 .

[13]  E. Ruch,et al.  The diagram lattice as structural principle A. New aspects for representations and group algebra of the symmetric group B. Definition of classification character, mixing character, statistical order, statistical disorder; A general principle for the time evolution of irreversible processes , 1975 .

[14]  E. Ruch,et al.  The principle of increasing mixing character and some of its consequences , 1976 .

[15]  M. Lostaglio,et al.  Markovian evolution of quantum coherence under symmetric dynamics , 2017, 1703.01826.

[16]  J. Gemmer,et al.  From single-shot towards general work extraction in a quantum thermodynamic framework , 2015, 1504.05061.

[17]  Thierry Paul,et al.  Quantum computation and quantum information , 2007, Mathematical Structures in Computer Science.

[18]  R. Xu,et al.  Theory of open quantum systems , 2002 .

[19]  Henrik Wilming,et al.  Third Law of Thermodynamics as a Single Inequality , 2017, 1701.07478.

[20]  Raymond Laflamme,et al.  Heat Bath Algorithmic Cooling with Spins: Review and Prospects , 2016 .

[21]  R. Renner,et al.  Gibbs-preserving maps outperform thermal operations in the quantum regime , 2014, 1406.3618.

[22]  Nicole Yunger Halpern,et al.  The resource theory of informational nonequilibrium in thermodynamics , 2013, 1309.6586.

[23]  A. E. Allahverdyan,et al.  Maximal work extraction from finite quantum systems , 2004 .

[24]  Quantum thermodynamics with local control. , 2016, Physical review. E.

[25]  Jonathan Oppenheim,et al.  A general derivation and quantification of the third law of thermodynamics , 2014, Nature Communications.

[26]  Matteo Lostaglio,et al.  Stochastic Independence as a Resource in Small-Scale Thermodynamics. , 2014, Physical review letters.

[27]  Jonathan Oppenheim,et al.  A Sufficient Set of Experimentally Implementable Thermal Operations for Small Systems , 2015, Physical Review X.

[28]  G. Gour,et al.  Low-temperature thermodynamics with quantum coherence , 2014, Nature Communications.

[29]  'Alvaro M. Alhambra,et al.  Fluctuating Work: From Quantum Thermodynamical Identities to a Second Law Equality , 2016, 1601.05799.

[30]  J Eisert,et al.  Second law of thermodynamics under control restrictions. , 2016, Physical review. E.

[31]  J. Åberg Fully quantum fluctuation theorems , 2016, 1601.01302.

[32]  E. Davies,et al.  Markovian master equations , 1974 .

[33]  J. Anders,et al.  Quantum thermodynamics , 2015, 1508.06099.

[34]  E B Davies Embeddable Markov Matrices , 2010 .

[35]  Nicole Yunger Halpern Toward Physical Realizations of Thermodynamic Resource Theories , 2015, 1509.03873.

[36]  A. Lenard Thermodynamical proof of the Gibbs formula for elementary quantum systems , 1978 .

[37]  M. Horodecki,et al.  Fundamental limitations for quantum and nanoscale thermodynamics , 2011, Nature Communications.

[38]  Ian T. Durham,et al.  Information and Interaction , 2017 .

[39]  E. Jaynes,et al.  Comparison of quantum and semiclassical radiation theories with application to the beam maser , 1962 .

[40]  Michal Horodecki,et al.  The second laws of quantum thermodynamics , 2013, Proceedings of the National Academy of Sciences.

[41]  J. Åberg Catalytic coherence. , 2013, Physical review letters.

[42]  T. Seligman,et al.  The mixing distance , 1978 .

[43]  E. Davies,et al.  Linear Operators and their Spectra , 2007 .

[44]  M. Horodecki,et al.  Limitations on the Evolution of Quantum Coherences: Towards Fully Quantum Second Laws of Thermodynamics. , 2015, Physical review letters.

[45]  Reck,et al.  Experimental realization of any discrete unitary operator. , 1994, Physical review letters.

[46]  C. Mead Mixing character and its application to irreversible processes in macroscopic systems , 1977 .

[47]  T. Rudolph,et al.  Quantum coherence, time-translation symmetry and thermodynamics , 2014, 1410.4572.

[48]  W. Pusz,et al.  Passive states and KMS states for general quantum systems , 1978 .

[49]  M. Horodecki,et al.  Decomposability and convex structure of thermal processes , 2017, 1707.06869.

[50]  Paul Skrzypczyk,et al.  The role of quantum information in thermodynamics—a topical review , 2015, 1505.07835.

[51]  Farrokh Vatan,et al.  Algorithmic cooling and scalable NMR quantum computers , 2001, Proceedings of the National Academy of Sciences of the United States of America.

[52]  Jun Yu Li,et al.  Heat-bath algorithmic cooling with correlated qubit-environment interactions , 2017, 1703.02999.

[53]  D. DiVincenzo,et al.  The Physical Implementation of Quantum Computation , 2000, quant-ph/0002077.

[54]  JochenGemmer From single-shot towards general work extraction in a quantum thermodynamic framework , 2015 .

[55]  F. Brandão,et al.  Resource theory of quantum states out of thermal equilibrium. , 2011, Physical review letters.

[56]  V. Scarani,et al.  Thermalizing quantum machines: dissipation and entanglement. , 2001, Physical review letters.

[57]  D. Janzing,et al.  Thermodynamic Cost of Reliability and Low Temperatures: Tightening Landauer's Principle and the Second Law , 2000, quant-ph/0002048.

[58]  Generalization of a theorem by Hardy, Littlewood, and Pólya , 1980 .

[59]  S. Chumakov,et al.  The Jaynes–Cummings Model , 2009 .

[60]  Nicole Yunger Halpern,et al.  Introducing one-shot work into fluctuation relations , 2014, 1409.3878.

[61]  K. Korzekwa Coherence, thermodynamics and uncertainty relations , 2016 .

[62]  M. Fannes,et al.  Davies maps for qubits and qutrits , 2009, 0911.5607.

[63]  Lluis Masanes,et al.  Work extraction from quantum systems with bounded fluctuations in work , 2016, Nature communications.

[64]  Jr. Arthur F. Veinott Least d-Majorized Network Flows with Inventory and Statistical Applications , 1971 .

[65]  Markus P. Mueller,et al.  Quantum Horn's lemma, finite heat baths, and the third law of thermodynamics , 2016, 1605.06092.