Limits of sympathetic cooling of fermions: The role of heat capacity of the coolant
- 20 April 2004
- journal article
- research article
- Published by American Physical Society (APS) in Physical Review A
- Vol. 69 (4) , 043611
- https://doi.org/10.1103/physreva.69.043611
Abstract
The sympathetic cooling of an initially degenerate Fermi gas by either an ideal Bose gas below or an ideal Boltzmann gas is investigated. It is shown that the efficiency of cooling by a Bose gas below is by no means reduced when its heat capacity becomes much less than that of the Fermi gas, where efficiency is measured by the decrease in the temperature of the Fermi gas per number of particles evaporated from the coolant. This contradicts the intuitive idea that an efficient coolant must have a large heat capacity. In contrast, for a Boltzmann gas a minimal value of the ratio of the heat capacities is indeed necessary to achieve and all of the particles must be evaporated.
Keywords
All Related Versions
This publication has 12 references indexed in Scilit:
- Fiftyfold Improvement in the Number of Quantum Degenerate Fermionic AtomsPhysical Review Letters, 2003
- Cooling Dynamics of Ultracold Two-Species Fermi-Bose MixturesPhysical Review Letters, 2003
- Fermi-Bose Quantum DegenerateMixture with Attractive InteractionPhysical Review Letters, 2002
- Reaching Fermi Degeneracy in Two-Species Optical Dipole TrapsPhysical Review Letters, 2002
- Two-Species Mixture of Quantum Degenerate Bose and Fermi GasesPhysical Review Letters, 2002
- Quasipure Bose-Einstein Condensate Immersed in a Fermi SeaPhysical Review Letters, 2001
- Observation of Fermi Pressure in a Gas of Trapped AtomsScience, 2001
- Kinetic theory of the evaporative cooling of a trapped gasPhysical Review A, 1996
- Evaporative cooling of magnetically trapped and compressed spin-polarized hydrogenPhysical Review B, 1986
- Statistical MechanicsPhysics Today, 1965