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Study of Macroscopic Coherence and Decoherence in the SQUID by Adiabatic Inversion

We suggest a procedure for demonstrating quantum coherence and measuring decoherence times between different fluxoid states of a SQUID by using ``adiabatic inversion'', where one macroscopic fluxoid state is smoothly transferred into the other, like a spin reversing direction by following a slowly moving magnetic field. This is accomplished by sweeping an external applied flux, and depends on a well-defined quantum phase between the two macroscopic states. Varying the speed of the sweep relative to the decoherence time permits one to move from the quantum regime, where such a well-defined phase exists, to the classical regime where it is lost and the inversion is inhibited. Thus observing whether inversion has taken place or not as a function of sweep speed offers the possibility of measuring the decoherence time. The main requirement for the feasibility of the scheme appears to be that the low temperature relaxation time among the quantum levels of the SQUID be long compared to other time scales of the problem. Applications to the ``quantum computer'', with the level system of the SQUID playing the role of the qbit, are briefly discussed.

preprint2000arXivOpen access
P. SilvestriniL. Stodolsky
cond-matquant-ph
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P. SilvestriniL. Stodolsky

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