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Coherent control of the cooperative branching ratio for nuclear x-ray pumping

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arxiv 1010.5134 v2 pith:DHRSBR7V submitted 2010-10-25 cond-mat.other quant-ph

Coherent control of the cooperative branching ratio for nuclear x-ray pumping

classification cond-mat.other quant-ph
keywords cooperativenuclearcontrolpumpingx-raydecaybranchingcoherent
verification ladder T0 review T1 audit T2 compute T3 formal T4 reserved
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Coherent control of nuclear pumping in a three level system driven by x-ray light is investigated. In single nuclei, the pumping performance is determined by the branching ratio of the excited state populated by the x-ray pulse. Our results are based on the observation that in ensembles of nuclei, cooperative excitation and decay leads to a greatly modified nuclear dynamics, which we characterize by a time-dependent cooperative branching ratio. We discuss prospects of steering the x-ray pumping by coherently controlling the cooperative decay. First, we study an ideal case with purely superradiant decay and perfect control of the cooperative emission. A numerical analysis of x-ray pumping in nuclear forward scattering with coherent control of the cooperative decay via externally applied magnetic fields is presented. Next, we provide an extended survey of nuclei suitable for our scheme, and propose proof-of-principle implementations already possible with typical M\"ossbauer nuclear systems such as $^{57}\mathrm{Fe}$. Finally, we discuss the application of such control techniques to the population or depletion of long-lived nuclear states.

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