Add to ORKGWith radiofrequency fields one can control ultracold atoms in magnetic traps. These fields couple the atomic spin states, and are used in evaporative cooling which can lead to Bose-Einstein condensation in the atom cloud. Also, they can be used in controlled release of the condensate from the trap, thus providing output couplers for atom lasers. In this paper we show that the time-dependent multistate models for these processes have exact solutions which are polynomials of the solutions of the corresponding two-state models. This allows simple, in many cases analytic descriptions for the time-dependent control of the magnetically trapped ultracold atoms
We show how to create a novel two-dimensional trap for ultracold atoms from a conventional magnetic ...
We consider optimization of a rubidium atom clock that uses magnetically trapped Bose condensed atom...
We demonstrate runaway evaporative cooling directly with a tightly confining optical-dipole trap and...
This thesis discusses several topics concerning Bose-Einstein condensation. We present two alternati...
We demonstrate that atoms in magnetically insensitive hyperfine states ($m = 0$) can be trapped effi...
Radio-frequency evaporation of atoms in a magnetic trap is the only way to obtain Bose-Einstein Cond...
A theoretical investigation for implementing a scheme of forced evaporative cooling in radio-frequen...
We present a new tool for Bose-Einstein condensation using evaporative cooling of magnetically trapp...
We experimentally and theoretically study the continuous accumulation of cold atoms from a magneto-o...
We demonstrate coherent microwave control of the rotational, hyperfine and Zeeman states of ultracol...
We report on dynamical simulations of Bose-Einstein condensation via evaporative cooling in an atomi...
We have realized a scheme for continuous loading of a magnetic trap (MT). ^{52}Cr atoms are continuo...
Demonstrating that despite loss processes, Bose-Einstein condensates can be formed in steady state i...
This Thesis contains details of the construction and characterisation of a compact apparatus for the...
We demonstrate that an appropriate sequence of laser pulses allows to condense a gas of trapped boso...
We show how to create a novel two-dimensional trap for ultracold atoms from a conventional magnetic ...
We consider optimization of a rubidium atom clock that uses magnetically trapped Bose condensed atom...
We demonstrate runaway evaporative cooling directly with a tightly confining optical-dipole trap and...
This thesis discusses several topics concerning Bose-Einstein condensation. We present two alternati...
We demonstrate that atoms in magnetically insensitive hyperfine states ($m = 0$) can be trapped effi...
Radio-frequency evaporation of atoms in a magnetic trap is the only way to obtain Bose-Einstein Cond...
A theoretical investigation for implementing a scheme of forced evaporative cooling in radio-frequen...
We present a new tool for Bose-Einstein condensation using evaporative cooling of magnetically trapp...
We experimentally and theoretically study the continuous accumulation of cold atoms from a magneto-o...
We demonstrate coherent microwave control of the rotational, hyperfine and Zeeman states of ultracol...
We report on dynamical simulations of Bose-Einstein condensation via evaporative cooling in an atomi...
We have realized a scheme for continuous loading of a magnetic trap (MT). ^{52}Cr atoms are continuo...
Demonstrating that despite loss processes, Bose-Einstein condensates can be formed in steady state i...
This Thesis contains details of the construction and characterisation of a compact apparatus for the...
We demonstrate that an appropriate sequence of laser pulses allows to condense a gas of trapped boso...
We show how to create a novel two-dimensional trap for ultracold atoms from a conventional magnetic ...
We consider optimization of a rubidium atom clock that uses magnetically trapped Bose condensed atom...
We demonstrate runaway evaporative cooling directly with a tightly confining optical-dipole trap and...