A proposal for the experimental detection of CSL induced random walk
A proposal for the experimental detection of CSL induced random walk
Continuous Spontaneous Localization (CSL) is one possible explanation for dynamically induced collapse of the wave-function during a quantum measurement. The collapse is mediated by a stochastic non-linear modification of the Schrödinger equation. A consequence of the CSL mechanism is an extremely tiny violation of energy-momentum conservation, which can, in principle, be detected in the laboratory via the random diffusion of a particle induced by the stochastic collapse mechanism.
In a paper in 2003, Collett and Pearle investigated the translational CSL diffusion of a sphere, and the rotational CSL diffusion of a disc, and showed that this effect dominates over the ambient environmental noise at low temperatures and extremely low pressures (about ten-thousandth of a pico-Torr). In the present paper, we revisit their analysis and argue that this stringent condition on pressure can be relaxed, and that the CSL effect can be seen at the pressure of about a pico-Torr. A similar analysis is provided for diffusion produced by gravity-induced decoherence, where the effect is typically much weaker than CSL. We also discuss the CSL induced random displacement of a quantum oscillator. Lastly, we propose possible experimental set-ups justifying that CSL diffusion is indeed measurable with the current technology.
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Ulbricht, Hendrik
5060dd43-2dc1-47f8-9339-c1a26719527d
Ulbricht, Hendrik
5060dd43-2dc1-47f8-9339-c1a26719527d
Ulbricht, Hendrik
(2014)
A proposal for the experimental detection of CSL induced random walk.
Scientific Reports, .
(In Press)
Abstract
Continuous Spontaneous Localization (CSL) is one possible explanation for dynamically induced collapse of the wave-function during a quantum measurement. The collapse is mediated by a stochastic non-linear modification of the Schrödinger equation. A consequence of the CSL mechanism is an extremely tiny violation of energy-momentum conservation, which can, in principle, be detected in the laboratory via the random diffusion of a particle induced by the stochastic collapse mechanism.
In a paper in 2003, Collett and Pearle investigated the translational CSL diffusion of a sphere, and the rotational CSL diffusion of a disc, and showed that this effect dominates over the ambient environmental noise at low temperatures and extremely low pressures (about ten-thousandth of a pico-Torr). In the present paper, we revisit their analysis and argue that this stringent condition on pressure can be relaxed, and that the CSL effect can be seen at the pressure of about a pico-Torr. A similar analysis is provided for diffusion produced by gravity-induced decoherence, where the effect is typically much weaker than CSL. We also discuss the CSL induced random displacement of a quantum oscillator. Lastly, we propose possible experimental set-ups justifying that CSL diffusion is indeed measurable with the current technology.
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A proposal for the experimental...1409.8204
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Accepted/In Press date: 3 December 2014
Additional Information:
Author Ulbricht confirms Arxiv record is accepted manuscript
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Local EPrints ID: 418113
URI: http://eprints.soton.ac.uk/id/eprint/418113
ISSN: 2045-2322
PURE UUID: cc5409a5-0f5a-483e-8c1c-9b8e3f5bdb89
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Date deposited: 22 Feb 2018 17:30
Last modified: 16 Mar 2024 03:58
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