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Recoil temperature

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In condensed matter physics and atomic physics, the recoil temperature is a fundamental lower limit of temperature attainable by some laser cooling schemes. When an atom decays from an excited electronic state at rest to a lower energy electronic state by the spontaneous emission of a photon, due to conservation of momentum, the atom gains momentum equivalent to the momentum of the photon. This kinetic energy gain corresponds to the recoil temperature of the atom. [1] The recoil temperature is

where

In general, the recoil temperature is below the Doppler cooling limit for atoms and molecules, so sub-Doppler cooling techniques such as Sisyphus cooling[2] are necessary to reach it. For example, the recoil temperature for the D2 lines of alkali atoms is typically on the order of 1 μK, in contrast with a Doppler cooling limit on the order of 100 μK.[3] However, the narrow-linewidth intercombination transitions of alkaline earth atoms such as strontium can have Doppler limits that are below their recoil limits, allowing laser cooling in narrow-line magneto-optical traps to the recoil limit without sub-Doppler cooling.[4]

Cooling beyond the recoil limit is possible using specific schemes such as Raman cooling.[5] Sub-recoil temperatures can also occur in the Lamb Dicke regime, where the recoil energy of a photon is smaller than a motional energy quantum; therefore the atom's state is effectively unchanged by recoil photons. [6]

References

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  1. ^ Metcalf and van der Straten (1999). Laser Cooling and Trapping. New York: Springer-Verlag. ISBN 0-387-98728-2.
  2. ^ Cohen-Tannoudji, C. (2004). Atoms in electromagnetic fields (2nd ed.). Singapore: World Scientific. ISBN 978-9812560193.
  3. ^ Cohen-Tannoudji, Claude N. (1 July 1998). "Nobel Lecture: Manipulating atoms with photons". Reviews of Modern Physics. 70 (3): 707–719. Bibcode:1998RvMP...70..707C. doi:10.1103/RevModPhys.70.707.
  4. ^ Stellmer, Simon (2013). "2.7.3 The red MOT". Degenerate quantum gases of strontium (PDF) (PhD thesis). University of Innsbruck. Retrieved 2024-02-16.
  5. ^ Reichel, J.; Morice, O.; Tino, G.M.; Salomon, C. (1994). "Subrecoil Raman Cooling of Cesium Atoms". Europhysics Letters. 28 (7): 477. Bibcode:1994EL.....28..477R. doi:10.1209/0295-5075/28/7/004. S2CID 250765474.
  6. ^ Eschner, Jürgen (2003). "Laser cooling of trapped ions". J. Opt. Soc. Am. B. 20 (5): 1003–1015. Bibcode:2003JOSAB..20.1003E. doi:10.1364/JOSAB.20.001003.