Laser pulse amplification and dispersion compensation in an effectively extended optical cavity containing Bose-Einstein condensates

We review and critically evaluate our proposal of a pulse amplification scheme based on two Bose-Einstein condensates inside the resonator of a mode-locked laser. Two condensates are used for compensating the group velocity dispersion. Ultraslow light propagation through the condensate leads to a co...

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Bibliographic Details
Published in:Journal of physics. B, Atomic, molecular, and optical physics Atomic, molecular, and optical physics, 2013-01, Vol.46 (1), p.15501-1-8
Main Authors: Tarhan, D, Sennaroglu, A, Müstecaplio lu, Ö E
Format: Article
Language:English
Subjects:
Amplification
atomic and molecular physics
atomic Bose-Einstein condensate
Bose-Einstein condensates
Classical and quantum physics: mechanics and fields
Compensation
Condensates
Dispersions
Exact sciences and technology
Fundamental areas of phenomenology (including applications)
Holes
Lasers
liquids and solids
Matter waves
mode-locking
Optics
Physics
Proposals
quantum gases
quantum optics and lasers
Wave optics
Wave propagation, transmission and absorption
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Summary:We review and critically evaluate our proposal of a pulse amplification scheme based on two Bose-Einstein condensates inside the resonator of a mode-locked laser. Two condensates are used for compensating the group velocity dispersion. Ultraslow light propagation through the condensate leads to a considerable increase in the cavity round-trip delay time, lowers the effective repetition rate of the laser, and hence scales up the output pulse energy. It has been argued recently that atom-atom interactions would make our proposal even more efficient. However, neither in our original proposal nor in the case of interactions, were limitations due to heating of the condensates by optical energy absorption taken into account. Our results show that there is a critical time of operation, 0.3 ms, for the optimal amplification factor, which is of the order of ∼102 at effective condensate lengths of the order of ∼50 μm. The bandwidth limitation of the amplifier on the minimum temporal width of the pulse that can be amplified with this technique is also discussed.
ISSN:0953-4075
1361-6455
DOI:10.1088/0953-4075/46/1/015501