Abstract

We study transitions of a particle between two wells, separated by a reservoir, under the condition that the particle is not detected in the reservoir. Conventional quantum trajectory theory predicts that such no-result continuous measurement would not affect these transitions. We demonstrate that it holds only for Markovian reservoirs (infinite bandwidth $\ensuremath{\Lambda}$). In the case of finite $\ensuremath{\Lambda}$, the probability of the particle's interwell transition is a function of the ratio $\ensuremath{\Lambda}/\ensuremath{\nu}$, where $\ensuremath{\nu}$ is the frequency of measurements. This scaling tells us that in the limit $\ensuremath{\nu}\ensuremath{\rightarrow}\ensuremath{\infty}$, the measurement freezes the initial state (the quantum Zeno effect), whereas for $\ensuremath{\Lambda}\ensuremath{\rightarrow}\ensuremath{\infty}$ it does not affect the particle's transition across the reservoir. The scaling is proved analytically by deriving a simple formula, which displays two regimes, with the Zeno effect and without the Zeno effect. It also supports a simple explanation of the Zeno effect entirely in terms of the energy-time uncertainty relation, with no explicit use of the projection postulate. Experimental tests of our predictions are discussed.

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