Sub-Planck spots of Schroedinger cats and quantum decoherence
Abstract
Heisenberg's principle1 states that the product of uncertainties of position and momentum should be no less than Planck's constant . This is usually taken to imply that phase space structures associated with sub-Planck ( ) scales do not exist, or, at the very least, that they do not matter. I show that this deeply ingrained prejudice is false: Non-local "Schr\"odinger cat" states of quantum systems confined to phase space volume characterized by `the classical action' A develop spotty structure on scales corresponding to sub-Planck a = 2 / A . Such structures arise especially quickly in quantum versions of classically chaotic systems (such as gases, modelled by chaotic scattering of molecules), that are driven into nonlocal Schr\"odinger cat -- like superpositions by the quantum manifestations of the exponential sensitivity to perturbations2. Most importantly, these sub-Planck scales are physically significant: a determines sensitivity of a quantum system (or of a quantum environment) to perturbations. Therefore sub-Planck a controls the effectiveness of decoherence and einselection caused by the environment3-8. It may also be relevant in setting limits on sensitivity of Schr\"odinger cats used as detectors.
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