Harvard University Department of Physics

Lene Hau's latest research has centered on cold atoms and Bose-Einstein condensation. Her group uses laser cooling to efficiently precool atoms to temperatures in the microkelvin regime. Subsequently, the atoms are trapped in a 4 Dee magnet and evaporatively cooled to nanokelvin temperatures, which results in the creation of Bose-Einstein condensates typically containing millions of atoms. The condensates are formed in an ultra high vacuum system constructed for easy access to and manipulation of cold atom clouds with light probes and mechanical structures.
Recently, the Hau group succeeded in reducing the light speed to 17 m/s (the speed of a racing bicycle) by optically inducing a quantum interference in a Bose-Einstein condensate. Ultra slow light creates a unique, new tool for probing the fundamental properties of Bose-Einstein condensates. Examples are: coupling of light and sound, an atom laser with controllable, localized output coupling, and studies of the dynamical formation of condensates. The system also exhibits extreme optical properties: Hau's group has demonstrated a nonlinear refractive index which is 14 orders of magnitude larger that the nonlinear index in an optical fiber and the largest ever measured by a factor of a million.

This has opened up a new territory of nonlinear optics at extremely low light levels, with interesting prospects for areas of quantum optics such as optical squeezing, quantum nondemolition, and studies of nonlocality. Intriguing potential applications of the large nonlinearities include creation of optical switches that work at the single photon level, dynamically programmable optical delay lines, and serial to parallel conversion.

A practical system could possibly be based on atom cooling with the use of diode lasers and micro-traps relating to another of Hau's interests: atomic wave guides for cold atoms. Hau and collaborators were the first to suggest a wave-guide for cold atoms based on a mechanical structure. The suggested "Kapitza guide" involves dynamical stabilization of atom motion around a metallic wire with time varying electric potentials. The resulting atom dynamics is intriguing and coupled with Bose-Einstein condensates, the wave-guide offers a unique possibility for studying chaos in a many body, interacting system. Furthermore, a condensate could adiabatically be transferred from the 4 Dee magnet to the wave-guide states, leading to output coupling and transport of coherent atomic matter waves. The Kapitza guide can thus be regarded as the matter wave analogue of optical fibers used as guiding structures for coherent light.