Evaporative Cooling Of Unitary Fermi Gas Mixtures In Optical Traps at Andrew Farr blog

Evaporative Cooling Of Unitary Fermi Gas Mixtures In Optical Traps. Using a single focused beam from a co2 laser, we confine a. Optical traps provide tight confinement and very long storage times for atomic gases. Sympathetic @ # cooling of fermionic 6li to degeneracy also has been achieved by using mixtures of 6li with bosonic 7li in a magnetic. Evaporative cooling stands as the prevailing method for achieving ultracold temperatures in atomic systems. We measure the scaling laws for the number of atoms and the cloud size as a function of trap depth for evaporative cooling of a unitary. Evaporative cooling in the optical trap efficiently brings the temperature down to the quantum degenerate regime, where the atomic. We measure the scaling laws for the number of atoms and the cloud size as a function of trap depth for evaporative cooling of a unitary.

Optical traps provide tight confinement and very long storage times for atomic gases. We measure the scaling laws for the number of atoms and the cloud size as a function of trap depth for evaporative cooling of a unitary. We measure the scaling laws for the number of atoms and the cloud size as a function of trap depth for evaporative cooling of a unitary. Evaporative cooling stands as the prevailing method for achieving ultracold temperatures in atomic systems. Using a single focused beam from a co2 laser, we confine a. Sympathetic @ # cooling of fermionic 6li to degeneracy also has been achieved by using mixtures of 6li with bosonic 7li in a magnetic. Evaporative cooling in the optical trap efficiently brings the temperature down to the quantum degenerate regime, where the atomic.

PPT Lecture II Non dissipative traps Evaporative cooling Bose

Evaporative Cooling Of Unitary Fermi Gas Mixtures In Optical Traps Using a single focused beam from a co2 laser, we confine a. We measure the scaling laws for the number of atoms and the cloud size as a function of trap depth for evaporative cooling of a unitary. Using a single focused beam from a co2 laser, we confine a. Evaporative cooling in the optical trap efficiently brings the temperature down to the quantum degenerate regime, where the atomic. Optical traps provide tight confinement and very long storage times for atomic gases. We measure the scaling laws for the number of atoms and the cloud size as a function of trap depth for evaporative cooling of a unitary. Sympathetic @ # cooling of fermionic 6li to degeneracy also has been achieved by using mixtures of 6li with bosonic 7li in a magnetic. Evaporative cooling stands as the prevailing method for achieving ultracold temperatures in atomic systems.