All-optical trapping of a degenerate Fermi gas has been demonstrated for the first time, offering a promising route for using an atomic gas to explore the mechanisms of superconductivity.The work was performed by Duke University physicists S. R. Granade, M. E. Gehm, K. M. O’Hara and J. E. Thomas.
First created in 1999, a degenerate Fermi gas is a sufficiently dense low-temperature gas of fermion atoms -- those atoms with an odd number of total particles (protons, neutrons, and electrons). They are the fermion cousins of Bose-Einstein condensates (BECs) first created in 1995.
Last year, a BEC was directly produced in an all-optical trap. The Duke group's work builds on their demonstration of the first stable optical trap for neutral atoms, namely, fermionic lithium, in early 1999 (Phys. Rev. Focus, 24 May 1999).
Until now, magnetic fields have been required to trap degenerate Fermi gases. Employing a stable, high-power CO2 laser, the Duke researchers create a kind of "optical bowl" for lithium-6 atoms, in which the hottest atoms evaporate like steam from hot soup. In this way, the researchers trap and cool an equal mixture of lithium atoms in spin-up and spin-down states.
This feat, which isn't possible in magnetic traps, points to perhaps the greatest advantage of the all-optical approach: It can confine essentially any combination of fermion species.
By contrast, if a magnetic trap confines the spin-up energy state of a fermion atom, it repels the spin-down version.
According to the Duke researchers, such equal mixtures of spin-up and spin-down are potentially ideal for forming neutrally charged analogs of superconducting "Cooper pairs" in Fermi gases.
This achievement of atomic-gas analogs of superconductivity is being intensely pursued in different ways by several groups, including the Duke researchers.
While the formation of Cooper pairs requires lower Fermi gas temperatures and stronger interactions between the atoms than have been achieved so far, such an accomplishment would permit tunable studies of superconductivity, and promises to result in a better understanding of the underlying theory.
(Reference: Granade, Gehm, O'Hara, and Thomas, Physical Review Letters, 25 March 2002; text available at this URL in PDF format.)
(Editor's Note: This story is based on PHYSICS NEWS UPDATE, the American Institute of Physics Bulletin of Physics News Number 580, March 13, 2002, by Phillip F. Schewe, Ben Stein, and James Riordon.)
[Contact: John Thomas]
25-Mar-2002
