Coherence in magnetic quantum tunneling
Abstract
Currently, spin tunneling at very low temperatures is assumed to proceed as an incoherent sequence of events that take place whenever a bias field h(t) that varies randomly with time t becomes sufficiently small, as in Landau-Zener transitions. We study the behavior of a suitably defined coherence time tp. Coherence effects become significant when tp >= th$, where th is the correlation time for h(t). The theory of tunneling of Prokof'ev and Stamp (PS), which rests on the assumption that tp <= th, is extended beyond this constraint. It is shown, both analytically and numerically, that tp >= th when th*dh <= h, where dh is the rms deviation of h. Equations that give tp and the tunneling rate as a function of th*dh both for th*dh>=h, where the theory of PS hold, and for th*dh <= h, where it does not, are derived.
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