This thesis presents experiments with a quantum-degenerate gas of bosonic atoms where interparticle interactions can be precisely controlled using a magnetic-field tun- able Feshbach resonance. Using our new apparatus, we have the capability to study either single species Bose-Einstein condensates of 85Rb or 87Rb, or a mixture of both species. With such a mixture we have created and studied the first ultracold heteronu- clear Feshbach molecules. Further work with two-component gases includes the creation of a dual-species BEC in which the miscibility of the two quantum fluids can be con- trolled. Finally, with a single species 85Rb condensate we have performed the first detailed measurements of the excitation spectrum of a BEC as a function of interaction strength. With strong interparticle interactions, we have observed that the excitation energy is smaller than that predicted by mean-field theory.
CY - Boulder N2 -This thesis presents experiments with a quantum-degenerate gas of bosonic atoms where interparticle interactions can be precisely controlled using a magnetic-field tun- able Feshbach resonance. Using our new apparatus, we have the capability to study either single species Bose-Einstein condensates of 85Rb or 87Rb, or a mixture of both species. With such a mixture we have created and studied the first ultracold heteronu- clear Feshbach molecules. Further work with two-component gases includes the creation of a dual-species BEC in which the miscibility of the two quantum fluids can be con- trolled. Finally, with a single species 85Rb condensate we have performed the first detailed measurements of the excitation spectrum of a BEC as a function of interaction strength. With strong interparticle interactions, we have observed that the excitation energy is smaller than that predicted by mean-field theory.
PB - University of Colorado Boulder PP - Boulder PY - 2007 TI - Experiments with a two-species Bose-Einstein condensate utilizing widely tunable interparticle interactions ER -