Dipolar Quantum Gases group

Stability of a unitary Bose gas.

Physical review letters 111:12 (2013) 125303

Authors:

Richard J Fletcher, Alexander L Gaunt, Nir Navon, Robert P Smith, Zoran Hadzibabic

Abstract:

We study the stability of a thermal (39)K Bose gas across a broad Feshbach resonance, focusing on the unitary regime, where the scattering length a exceeds the thermal wavelength λ. We measure the general scaling laws relating the particle-loss and heating rates to the temperature, scattering length, and atom number. Both at unitarity and for positive a<<λ we find agreement with three-body theory. However, for a<0 and away from unitarity, we observe significant four-body decay. At unitarity, the three-body loss coefficient, L(3) proportional λ(4), is 3 times lower than the universal theoretical upper bound. This reduction is a consequence of species-specific Efimov physics and makes (39)K particularly promising for studies of many-body physics in a unitary Bose gas.

Stability of a unitary Bose gas

(2013)

Authors:

Richard J Fletcher, Alexander L Gaunt, Nir Navon, Robert P Smith, Zoran Hadzibabic

Effects of Interactions on Bose-Einstein Condensation of an Atomic Gas

Chapter in Physics of Quantum Fluids, Springer (2013) 16

Authors:

SMITH, Z Hadzibabic

A superheated Bose-condensed gas

Nature Physics Springer Nature 9:5 (2013) 271-274

Authors:

Alexander L Gaunt, Richard J Fletcher, Robert P Smith, Zoran Hadzibabic

Bose-Einstein condensation of atoms in a uniform potential.

Physical review letters 110:20 (2013) 200406

Authors:

Alexander L Gaunt, Tobias F Schmidutz, Igor Gotlibovych, Robert P Smith, Zoran Hadzibabic

Abstract:

We have observed the Bose-Einstein condensation of an atomic gas in the (quasi)uniform three-dimensional potential of an optical box trap. Condensation is seen in the bimodal momentum distribution and the anisotropic time-of-flight expansion of the condensate. The critical temperature agrees with the theoretical prediction for a uniform Bose gas. The momentum distribution of a noncondensed quantum-degenerate gas is also clearly distinct from the conventional case of a harmonically trapped sample and close to the expected distribution in a uniform system. We confirm the coherence of our condensate in a matter-wave interference experiment. Our experiments open many new possibilities for fundamental studies of many-body physics.