Add to ORKGWe observe bright matter-wave solitons form during the collapse of 85Rb condensates in a three-dimensional (3D) magnetic trap. The collapse is induced by using a Feshbach resonance to suddenly switch the atomic interactions from repulsive to attractive. Remnant condensates containing several times the critical number of atoms for the onset of instability are observed to survive the collapse. Under these conditions a highly robust configuration of 3D solitons forms such that each soliton satisfies the condition for stability and neighboring solitons exhibit repulsive interactions
Bose-Einstein condensation has been achieved in a magnetically trapped sample of 85Rb atoms. Long-li...
A Bose-Einstein condensate represents the most 'classical' form of a matter wave, just as an optical...
We describe a model of dynamic Bose-Einstein condensates near a Feshbach resonance that is computati...
We observe bright matter-wave solitons form during the collapse of 85Rb condensates in a three-dimen...
We review recent experimental and theoretical work on the creation of bright matter wave solitons i...
Bright solitons are non-dispersive wave solutions, arising in a diverse range of nonlinear, one-dime...
The point of instability of a Bose-Einstein condensate (BEC) due to attractive interactions was stud...
This thesis presents the development of an experimental apparatus to produce Bose-Einstein condensat...
The collisions of three-dimensional bright solitary matter waves formed from atomic Bose–Einstein co...
Motivated by recent experimental observations, we study theoretically multiple bright solitary waves...
We study suppression of the collapse and stabilization of matter-wave solitons by means of time-peri...
We model the formation of bright atomic solitons due to collapse of Bose-Einstein condensates with a...
We experimentally study the excitation modes of bright matter-wave solitons in a quasi-one-dimension...
Microcavity polaritons are two-dimensional bosonic fluids with strong nonlinearities, composed of c...
We solve the Gross-Pitaevskii equation numerically for the collapse induced by a switch from positiv...
Bose-Einstein condensation has been achieved in a magnetically trapped sample of 85Rb atoms. Long-li...
A Bose-Einstein condensate represents the most 'classical' form of a matter wave, just as an optical...
We describe a model of dynamic Bose-Einstein condensates near a Feshbach resonance that is computati...
We observe bright matter-wave solitons form during the collapse of 85Rb condensates in a three-dimen...
We review recent experimental and theoretical work on the creation of bright matter wave solitons i...
Bright solitons are non-dispersive wave solutions, arising in a diverse range of nonlinear, one-dime...
The point of instability of a Bose-Einstein condensate (BEC) due to attractive interactions was stud...
This thesis presents the development of an experimental apparatus to produce Bose-Einstein condensat...
The collisions of three-dimensional bright solitary matter waves formed from atomic Bose–Einstein co...
Motivated by recent experimental observations, we study theoretically multiple bright solitary waves...
We study suppression of the collapse and stabilization of matter-wave solitons by means of time-peri...
We model the formation of bright atomic solitons due to collapse of Bose-Einstein condensates with a...
We experimentally study the excitation modes of bright matter-wave solitons in a quasi-one-dimension...
Microcavity polaritons are two-dimensional bosonic fluids with strong nonlinearities, composed of c...
We solve the Gross-Pitaevskii equation numerically for the collapse induced by a switch from positiv...
Bose-Einstein condensation has been achieved in a magnetically trapped sample of 85Rb atoms. Long-li...
A Bose-Einstein condensate represents the most 'classical' form of a matter wave, just as an optical...
We describe a model of dynamic Bose-Einstein condensates near a Feshbach resonance that is computati...