dorsal/arxiv
View SchemaOn the nature of spin, inertia and gravity of a moving canonical particle
| Authors | Volodymyr Krasnoholovets |
|---|---|
| Categories | |
| ArXiv ID | quant-ph/0103110 |
| URL | https://arxiv.org/abs/quant-ph/0103110 |
| Journal | Indian Journal of Theoretical Physics, vol. 48, no. 2, pp. 97-132 (2000) |
Abstract
It is suggested that a moving canonical particle interacts with a vacuum regarded as a "soft" cellular space. The interaction results into the emergence of elementary excitations of space - inertons - surrounding the particle. It is assumed that such a motion leads not only to the spatial oscillation of the particle along a path but to the oscillation of the particle centre-of-mass as well. This phenomenon culminating in the anisotropic pulsation of the particle is associated with the notion of spin. The particle-space interaction is treated as the origin of the matter waves, which are identified with the particle inertia and inertons surrounding the moving particle are considered as carriers of its inert properties. Inertons are also identified with real carriers of the gravitational interaction and the range of the particle gravitational potential is evaluated by the inerton cloud amplitude $\Lambda=\lambda c/v$, where $\lambda$ is the de Broglie wavelength, $c$ and $v$ are the velocity of light and the particle respectively. The nature of the phase transition that occurs in a quantum system when one should pass from the description based on the Schroedinger formalism to that of resting on the Dirac one is explained in detail.
{
"annotation_id": "36b1e682-fdf7-46ae-a59c-3d8c3ce1f615",
"date_created": "2026-03-02T18:01:42.576000Z",
"date_modified": "2026-03-02T18:01:42.576000Z",
"file_hash": "0a8f29621e90d389af1a2a83d78ad195b11a7c674f726c76d5c1791df48d5857",
"private": false,
"record": {
"abstract": "It is suggested that a moving canonical particle interacts with a vacuum\nregarded as a \"soft\" cellular space. The interaction results into the emergence\nof elementary excitations of space - inertons - surrounding the particle. It is\nassumed that such a motion leads not only to the spatial oscillation of the\nparticle along a path but to the oscillation of the particle centre-of-mass as\nwell. This phenomenon culminating in the anisotropic pulsation of the particle\nis associated with the notion of spin. The particle-space interaction is\ntreated as the origin of the matter waves, which are identified with the\nparticle inertia and inertons surrounding the moving particle are considered as\ncarriers of its inert properties. Inertons are also identified with real\ncarriers of the gravitational interaction and the range of the particle\ngravitational potential is evaluated by the inerton cloud amplitude\n$\\Lambda=\\lambda c/v$, where $\\lambda$ is the de Broglie wavelength, $c$ and\n$v$ are the velocity of light and the particle respectively. The nature of the\nphase transition that occurs in a quantum system when one should pass from the\ndescription based on the Schroedinger formalism to that of resting on the Dirac\none is explained in detail.",
"arxiv_id": "quant-ph/0103110",
"authors": [
"Volodymyr Krasnoholovets"
],
"categories": [
"quant-ph",
"gr-qc",
"hep-th",
"nucl-th"
],
"journal_ref": "Indian Journal of Theoretical Physics, vol. 48, no. 2, pp. 97-132\n (2000)",
"title": "On the nature of spin, inertia and gravity of a moving canonical particle",
"url": "https://arxiv.org/abs/quant-ph/0103110"
},
"schema_id": "dorsal/arxiv",
"source": {
"execution_id": "d0dab423-5624-4c2c-a90b-83b9609347e2",
"id": "arXiv Dataset IDs",
"type": "Model",
"variant": "snapshot-2026-03-01",
"version": "0.1.0"
},
"user_id": 1000002
}