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    This (lowercase (translateProductType product.productType)) has been cited by the following publications. This list is generated based on data provided by CrossRef.
    Naderali, R. Motiei, H. and Jafari, A. 2013. Creation of entangled W states of four two-level atoms in a cavity via quadrapod adiabatic passage. Optical and Quantum Electronics, Vol. 45, Issue. 2, p. 97.
    Denur, Jack 2010. The energy-time uncertainty principle and quantum phenomena. American Journal of Physics, Vol. 78, Issue. 11, p. 1132.
    Zhi-Fang, Feng Wei-Dong, Li Lian-Tuan, Xiao and Suo-Tang, Jia 2009. Sub-natural linewidth of the probe absorption spectrum in a cold Cs atom–molecule system. Chinese Physics B, Vol. 18, Issue. 11, p. 4901.
    Rong, Yu Jia-Hua, Li Liu-Gang, Si and Xiao-Xue, Yang 2009. Microwave-Controlled Light-Pulse Propagation in a Driven A-Type Atomic System with Two-Folded Levels. Communications in Theoretical Physics, Vol. 52, Issue. 1, p. 137.
    Xiao-Juan, Liu Mao-Fa, Fang and Qing-Ping, Zhou 2004. Entropy and Entanglement of the Electromagnetically Induced Transparency System. Chinese Physics Letters, Vol. 21, Issue. 6, p. 1071.
    Silva, F Mompart, J Ahufinger, V and Corbalán, R 2000. Electromagnetically induced transparency in Doppler-broadened three-level systems with resonant standing-wave drive. Europhysics Letters (EPL), Vol. 51, Issue. 3, p. 286.
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  • Print publication year: 1997
  • Online publication date: June 2012

7 - Lasing without inversion and other effects of atomic coherence and interference

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Summary

Quantum coherence and correlations in atomic and radiation physics have led to many interesting and unexpected consequences. For example, an atomic ensemble prepared in a coherent superposition of states yields the Hanle effect, quantum beats, photon echo, self-induced transparency, and coherent Raman beats. In fact, in Section 1.4, we saw that the quantum beat effect provides one of the most compelling reasons for quantizing the radiation field.

A further interesting consequence of preparing an atomic system in a coherent superposition of states is that, under certain conditions, it is possible for atomic coherence to cancel absorption. Such atomic states are called trapping states†. The observation of nonabsorbing resonances via atomic coherence and interference impacts on the concepts of lasing without inversion (LWI),‡ enhancement of the index of refraction accompanied by vanishing absorption, and electromagnetically induced transparency.

In lasing without inversion, the essential idea is the absorption cancellation by atomic coherence and interference. This phenomenon is also the essence of electromagnetically induced transparency. Usually this is accomplished in three-level atomic systems in which there are two coherent routes for absorption that can destructively interfere, thus leading to the cancellation of absorption. A small population in the excited state can thus lead to net gain. A related phenomenon is that of resonantly enhanced refractive index without absorption in an ensemble of phase-coherent atoms (phaseonium). In a phaseonium gas with no population in the excited level, the absorption cancellation always coincides with vanishing refractivity.

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Quantum Optics
  • Online ISBN: 9780511813993
  • Book DOI: https://doi.org/10.1017/CBO9780511813993
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