dorsal/arxiv
View SchemaWavefunction Collapse and Random Walk
| Authors | Brian Collett, Philip Pearle |
|---|---|
| Categories | |
| ArXiv ID | quant-ph/0208009 |
| URL | https://arxiv.org/abs/quant-ph/0208009 |
| DOI | 10.1023/A:1026048530567 |
Abstract
Wavefunction collapse models modify Schrodinger's equation so that it describes the rapid evolution of a superposition of macroscopically distinguishable states to one of them. This provides a phenomenological basis for a physical resolution to the so-called "measurement problem." Such models have experimentally testable differences from standard quantum theory. The most well developed such model at present is the Continuous Spontaneous Localization (CSL) model in which a fluctuating classical field interacts with particles to cause collapse. One "side effect" of this interaction is that the field imparts momentum to particles, causing a small blob of matter to undergo random walk. Here we explore this in order to supply predictions which could be experimentally tested. We examine the translational diffusion of a sphere and a disc, and the rotational diffusion of a disc, according to CSL. For example, we find that a disc of radius 2 cdot 10^{-5} cm and thickness 0.5 cdot 10^{-5} cm diffuses through 2 pi rad in about 70sec (this assumes the "standard" CSL parameter values). The comparable rms diffusion of standard quantum theory is smaller than this by a factor 10^-3. At the reported pressure of < 5 cdot10^{-17} Torr, achieved at 4.2^{circ} K, the mean time between air molecule collisions with the disc is approximately 45min (and the diffusion caused by photon collisons is utterly negligible). This is ample time for observation of the putative CSL diffusion over a wide range of parameters. This encourages consideration of how such an experiment may actually be performed, and the paper closes with some thoughts on this subject
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"abstract": "Wavefunction collapse models modify Schrodinger\u0027s equation so that it\ndescribes the rapid evolution of a superposition of macroscopically\ndistinguishable states to one of them. This provides a phenomenological basis\nfor a physical resolution to the so-called \"measurement problem.\" Such models\nhave experimentally testable differences from standard quantum theory. The most\nwell developed such model at present is the Continuous Spontaneous Localization\n(CSL) model in which a fluctuating classical field interacts with particles to\ncause collapse. One \"side effect\" of this interaction is that the field imparts\nmomentum to particles, causing a small blob of matter to undergo random walk.\nHere we explore this in order to supply predictions which could be\nexperimentally tested. We examine the translational diffusion of a sphere and a\ndisc, and the rotational diffusion of a disc, according to CSL. For example, we\nfind that a disc of radius 2 cdot 10^{-5} cm and thickness 0.5 cdot 10^{-5} cm\ndiffuses through 2 pi rad in about 70sec (this assumes the \"standard\" CSL\nparameter values). The comparable rms diffusion of standard quantum theory is\nsmaller than this by a factor 10^-3. At the reported pressure of \u003c 5\ncdot10^{-17} Torr, achieved at 4.2^{circ} K, the mean time between air molecule\ncollisions with the disc is approximately 45min (and the diffusion caused by\nphoton collisons is utterly negligible). This is ample time for observation of\nthe putative CSL diffusion over a wide range of parameters.\n This encourages consideration of how such an experiment may actually be\nperformed, and the paper closes with some thoughts on this subject",
"arxiv_id": "quant-ph/0208009",
"authors": [
"Brian Collett",
"Philip Pearle"
],
"categories": [
"quant-ph"
],
"doi": "10.1023/A:1026048530567",
"title": "Wavefunction Collapse and Random Walk",
"url": "https://arxiv.org/abs/quant-ph/0208009"
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