dorsal/arxiv
View SchemaThe vacuum interpretation of quantum mechanics and the vacuum universe
| Authors | Ding-Yu Chung |
|---|---|
| Categories | |
| ArXiv ID | quant-ph/0110159 |
| URL | https://arxiv.org/abs/quant-ph/0110159 |
Abstract
Quantum mechanics is interpreted by the adjacent vacuum that behaves as a virtual particle to be absorbed and emitted by its matter. As described in the vacuum universe model, the adjacent vacuum is derived from the pre-inflationary universe in which the pre-adjacent vacuum is absorbed by the pre-matter. This absorbed pre-adjacent vacuum is emitted to become the added space for the inflation in the inflationary universe whose space-time is separated from the pre-inflationary universe. This added space is the adjacent vacuum. The absorption of the adjacent vacuum as the added space results in the adjacent zero space (no space), Quantum mechanics is the interaction between matter and the three different types of vacuum: the adjacent vacuum, the adjacent zero space, and the empty space. The absorption of the adjacent vacuum results in the empty space superimposed with the adjacent zero space, confining the matter in the form of particle. When the absorbed vacuum is emitted, the adjacent vacuum can be anywhere instantly in the empty space superimposed with the adjacent zero space where any point can be the starting point (zero point) of space-time. Consequently, the matter that expands into the adjacent vacuum has the probability to be anywhere instantly in the form of wavefunction. In the vacuum universe model, the universe not only gains its existence from the vacuum but also fattens itself with the vacuum. During the inflation, the adjacent vacuum also generates the periodic table of elementary particles to account for all elementary particles and their masses in a good agreement with the observed values.
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"abstract": "Quantum mechanics is interpreted by the adjacent vacuum that behaves as a\nvirtual particle to be absorbed and emitted by its matter. As described in the\nvacuum universe model, the adjacent vacuum is derived from the pre-inflationary\nuniverse in which the pre-adjacent vacuum is absorbed by the pre-matter. This\nabsorbed pre-adjacent vacuum is emitted to become the added space for the\ninflation in the inflationary universe whose space-time is separated from the\npre-inflationary universe. This added space is the adjacent vacuum. The\nabsorption of the adjacent vacuum as the added space results in the adjacent\nzero space (no space), Quantum mechanics is the interaction between matter and\nthe three different types of vacuum: the adjacent vacuum, the adjacent zero\nspace, and the empty space. The absorption of the adjacent vacuum results in\nthe empty space superimposed with the adjacent zero space, confining the matter\nin the form of particle. When the absorbed vacuum is emitted, the adjacent\nvacuum can be anywhere instantly in the empty space superimposed with the\nadjacent zero space where any point can be the starting point (zero point) of\nspace-time. Consequently, the matter that expands into the adjacent vacuum has\nthe probability to be anywhere instantly in the form of wavefunction. In the\nvacuum universe model, the universe not only gains its existence from the\nvacuum but also fattens itself with the vacuum. During the inflation, the\nadjacent vacuum also generates the periodic table of elementary particles to\naccount for all elementary particles and their masses in a good agreement with\nthe observed values.",
"arxiv_id": "quant-ph/0110159",
"authors": [
"Ding-Yu Chung"
],
"categories": [
"quant-ph"
],
"title": "The vacuum interpretation of quantum mechanics and the vacuum universe",
"url": "https://arxiv.org/abs/quant-ph/0110159"
},
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