Radio-frequency spectroscopy of {sup 6}Li p-wave molecules: Towards photoemission spectroscopy of a p-wave superfluid

Radio-frequency spectroscopy of {sup 6}Li p-wave molecules: Towards photoemission spectroscopy of a p-wave superfluid

We study rf spectroscopy of a lithium gas with the goal to explore the possibilities for photoemission spectroscopy of a strongly interacting p-wave Fermi gas. Radio-frequency spectra of quasibound p-wave molecules and of free atoms in the vicinity of the p-wave Feshbach resonance located at 159.15...

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Veröffentlicht in:Physical review. A, Atomic, molecular, and optical physics Atomic, molecular, and optical physics, 2010-06, Vol.81 (6)
Hauptverfasser: Maier, R. A. W., Marzok, C., Zimmermann, C., Courteille, Ph. W., Instituto de Fisica de Sao Carlos, Universidade de Sao Paulo, Caixa Postal 369, Sao Carlos-SP 13560-970
Format: Artikel
Sprache:eng
Schlagworte:
ALKALI METALS
ANISOTROPY
ATOMIC AND MOLECULAR PHYSICS
ATOMS
CONDENSED MATTER PHYSICS, SUPERCONDUCTIVITY AND SUPERFLUIDITY
ELECTROMAGNETIC RADIATION
ELEMENTS
EMISSION
EMISSION SPECTRA
EMISSION SPECTROSCOPY
ENERGY GAP
FERMI GAS
ISOTOPES
LIGHT NUCLEI
LITHIUM
LITHIUM 6
LITHIUM ISOTOPES
MAGNETIC FIELDS
METALS
MOLECULES
NUCLEI
ODD-ODD NUCLEI
P WAVES
PARTIAL WAVES
PHOTOEMISSION
RADIATIONS
RADIOWAVE RADIATION
RESONANCE
SECONDARY EMISSION
SPECTRA
SPECTROSCOPY
STABLE ISOTOPES
SUPERFLUIDITY
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Zusammenfassung:We study rf spectroscopy of a lithium gas with the goal to explore the possibilities for photoemission spectroscopy of a strongly interacting p-wave Fermi gas. Radio-frequency spectra of quasibound p-wave molecules and of free atoms in the vicinity of the p-wave Feshbach resonance located at 159.15 G are presented. The spectra are free of detrimental final-state effects. The observed relative magnetic-field shifts of the molecular and atomic resonances confirm earlier measurements realized with direct rf association. Furthermore, evidence of molecule production by adiabatically ramping the magnetic field is observed. Finally, we propose the use of a one-dimensional optical lattice to study anisotropic superfluid gaps as most direct proof of p-wave superfluidity.
ISSN:1050-2947
1094-1622
DOI:10.1103/PHYSREVA.81.064701