Collective excitation of bosonic quantum Hall state

Abstract: The recent developments in the theory of rapidly rotating Bose atoms have been reviewed in this article. Rotation leads to the development of quantized-vortices, that cluster into a vortex array, exactly to how superfluid helium behaves. Theoretically, a number of strongly correlated phases are projected to exist in this domain, which might be thought of as bosonic counterparts of fractional quantum Hall effect (FQHE). It is now possible for bosons associating with a short-range interaction to exhibit a FQHE, because the system of neutral bosons in a fast rotating atomic trap is analogous to charged bosons placed in a fictitious magnetic field. The neutral collective spin-conserving and spin-flip excitation for the rotating ultra-cold dilute Bose atoms in the FQHE domain are being discussed. We have introduced a realistic interaction between the Bose particles together with long-range interaction and presented a short review article about various fractional quantum Hall states and their spin conserving and spin reversed collective modes.