Thermalisation Explained

In physics, thermalisation (or thermalization) is the process of physical bodies reaching thermal equilibrium through mutual interaction. In general, the natural tendency of a system is towards a state of equipartition of energy and uniform temperature that maximizes the system's entropy. Thermalisation, thermal equilibrium, and temperature are therefore important fundamental concepts within statistical physics, statistical mechanics, and thermodynamics; all of which are a basis for many other specific fields of scientific understanding and engineering application.

Examples of thermalisation include:

The hypothesis, foundational to most introductory textbooks treating quantum statistical mechanics,[4] assumes that systems go to thermal equilibrium (thermalisation). The process of thermalisation erases local memory of the initial conditions. The eigenstate thermalisation hypothesis is a hypothesis about when quantum states will undergo thermalisation and why.

Not all quantum states undergo thermalisation. Some states have been discovered which do not (see below), and their reasons for not reaching thermal equilibrium are unclear .

Theoretical description

The process of equilibration can be described using the H-theorem or the relaxation theorem,[5] see also entropy production.

Systems resisting thermalisation

Some such phenomena resisting the tendency to thermalize include (see, e.g., a quantum scar):[6]

Other systems that resist thermalisation and are better understood are quantum integrable systems[19] and systems with dynamical symmetries.[20]

References

  1. Web site: Collisions and Thermalization. sdphca.ucsd.edu. 2018-05-14.
  2. Web site: NRC: Glossary -- Thermalization. www.nrc.gov. en. 2018-05-14.
  3. Andersson . Olof . Kemerink . Martijn . December 2020 . Enhancing Open-Circuit Voltage in Gradient Organic Solar Cells by Rectifying Thermalization Losses . Solar RRL . en . 4 . 12 . 2000400 . 10.1002/solr.202000400 . 226343918 . 2367-198X. free .
  4. Sakurai JJ. 1985. Modern Quantum Mechanics. Menlo Park, CA: Benjamin/Cummings
  5. Reid. James C.. Evans. Denis J.. Searles. Debra J.. 2012-01-11. Communication: Beyond Boltzmann's H-theorem: Demonstration of the relaxation theorem for a non-monotonic approach to equilibrium. The Journal of Chemical Physics. 136. 2. 021101. 10.1063/1.3675847. 22260556. 0021-9606. 1885/16927. free.
  6. Web site: March 20, 2019 . Quantum Scarring Appears to Defy Universe's Push for Disorder . March 24, 2019 . Quanta Magazine.
  7. Heller . Eric J. . 1984-10-15 . Bound-State Eigenfunctions of Classically Chaotic Hamiltonian Systems: Scars of Periodic Orbits . Physical Review Letters . 53 . 16 . 1515–1518 . 10.1103/PhysRevLett.53.1515. 1984PhRvL..53.1515H .
  8. Kaplan . L . 1999-01-01 . Scars in quantum chaotic wavefunctions . Nonlinearity . en . 12 . 2 . R1–R40 . 10.1088/0951-7715/12/2/009 . 250793219 . 0951-7715.
  9. Kaplan . L. . Heller . E. J. . 1998-04-10 . Linear and Nonlinear Theory of Eigenfunction Scars . Annals of Physics . en . 264 . 2 . 171–206 . 10.1006/aphy.1997.5773 . chao-dyn/9809011 . 1998AnPhy.264..171K . 120635994 . 0003-4916.
  10. Book: Heller, Eric . The Semiclassical Way to Dynamics and Spectroscopy . 5 June 2018 . Princeton University Press . 978-1-4008-9029-3 . 1104876980.
  11. Keski-Rahkonen . J. . Ruhanen . A. . Heller . E. J. . Räsänen . E. . 2019-11-21 . Quantum Lissajous Scars . Physical Review Letters . 123 . 21 . 214101 . 10.1103/PhysRevLett.123.214101. 31809168 . 1911.09729 . 2019PhRvL.123u4101K . 208248295 .
  12. Luukko . Perttu J. J. . Drury . Byron . Klales . Anna . Kaplan . Lev . Heller . Eric J. . Räsänen . Esa . 2016-11-28 . Strong quantum scarring by local impurities . Scientific Reports . en . 6 . 1 . 37656 . 10.1038/srep37656 . 2045-2322 . 5124902 . 27892510. 1511.04198 . 2016NatSR...637656L .
  13. Keski-Rahkonen . J. . Luukko . P. J. J. . Kaplan . L. . Heller . E. J. . Räsänen . E. . 2017-09-20 . Controllable quantum scars in semiconductor quantum dots . Physical Review B . 96 . 9 . 094204 . 10.1103/PhysRevB.96.094204. 1710.00585 . 2017PhRvB..96i4204K . 119083672 .
  14. Keski-Rahkonen . J . Luukko . P J J . Åberg . S . Räsänen . E . 2019-01-21 . Effects of scarring on quantum chaos in disordered quantum wells . Journal of Physics: Condensed Matter . en . 31 . 10 . 105301 . 10.1088/1361-648x/aaf9fb . 30566927 . 1806.02598 . 51693305 . 0953-8984.
  15. Book: Keski-Rahkonen, Joonas . Quantum Chaos in Disordered Two-Dimensional Nanostructures . 2020 . Tampere University . 978-952-03-1699-0 . en.
  16. 10.1146/annurev-conmatphys-031214-014726. Many-Body Localization and Thermalization in Quantum Statistical Mechanics. Annual Review of Condensed Matter Physics. 6. 15–38. 2015. Nandkishore. Rahul. Huse. David A.. Abanin. D. A.. Serbyn. M.. Papić. Z.. 2015ARCMP...6...15N. 1404.0686. 118465889.
  17. 10.1126/science.aaf8834. 27339981. Exploring the many-body localization transition in two dimensions. Science. 352. 6293. 1547–1552. 2016. Choi. J.-y.. Hild. S.. Zeiher. J.. Schauss. P.. Rubio-Abadal. A.. Yefsah. T.. Khemani. V.. Huse. D. A.. Bloch. I.. Gross. C.. 2016Sci...352.1547C. 1604.04178. 35012132.
  18. 10.1103/PhysRevLett.120.070501. 29542978. Exploring Localization in Nuclear Spin Chains. Physical Review Letters. 120. 7. 070501. 2018. Wei. Ken Xuan. Ramanathan. Chandrasekhar. Cappellaro. Paola. 2018PhRvL.120g0501W. 1612.05249. 4005098.
  19. Caux. Jean-Sébastien. Essler. Fabian H. L.. 2013-06-18. Time Evolution of Local Observables After Quenching to an Integrable Model. Physical Review Letters. 110. 25. 257203. 10.1103/PhysRevLett.110.257203. 23829756. 3549427. free. 1301.3806.
  20. Buča. Berislav. Tindall. Joseph. Jaksch. Dieter. 2019-04-15. Non-stationary coherent quantum many-body dynamics through dissipation. Nature Communications. en. 10. 1. 1730. 10.1038/s41467-019-09757-y. 2041-1723. 6465298. 30988312.