Title :
Optically-trapped Fermi gas
Author :
Gehm, Michael E. ; Granade, S.R. ; Chang, M.-S. ; O´Hara, Kenneth M. ; Thomas, J.E.
Author_Institution :
Dept. of Phys., Duke Univ., Durham, NC, USA
Abstract :
Summary form only given. Cold, dense gases of fermions offer exciting new opportunities for fundamental studies of quantum degeneracy, collective behavior, and superfluidity. Fermionic /sup 6/Li has been the subject of numerous theoretical treatments. This is due in part to its anomalously large and negative triplet scattering length, a/sub T/=-2160 a/sub O/, which arises from a near zero energy resonance. The large scattering length leads to two-state mixtures which are predicted to undergo a transition to a superfluid state at a relatively high temperature. To increase our well depth, we retroreflect the CO/sub 2/ beam which forms our optical trap, nearly doubling the intensity of the trapping field and thus the well depth. We will discuss this technique and its effect on evaporative cooling, and report our progress towards producing a degenerate gas of /sup 6/Li.
Keywords :
fermions; laser cooling; lithium; quantum optics; superfluidity; /sup 6/Li; CO/sub 2/; cold dense gases; collective behavior; degenerate gas; evaporative cooling; fermionic /sup 6/Li; negative triplet scattering; optical trap; optically-trapped Fermi gas; quantum degeneracy; retroreflected CO/sub 2/ beam; superfluid state; superfluidity; trapping field intensity; Atom lasers; Atom optics; Atomic beams; Charge carrier processes; Cooling; Gas lasers; Laser beams; Laser modes; Optimized production technology; Temperature;
Conference_Titel :
Quantum Electronics and Laser Science Conference, 2001. QELS '01. Technical Digest. Summaries of Papers Presented at the
Conference_Location :
Baltimore, MD, USA
Print_ISBN :
1-55752-663-X
DOI :
10.1109/QELS.2001.962210
