Physical Dimensions/Units and Universal Constants

Their Invariance in Special and General Relativity

verfasst von: Friedrich W. Hehl, Claus Lämmerzahl
Abstract: The theory of physical dimensions and units in physics is outlined. This includes a discussion of the universal applicability and superiority of quantity equations. The International System of Units (SI) is one example thereof. By analyzing mechanics and electrodynamics, it naturally leads one, besides the dimensions of length and time, to the fundamental units of action h, electric charge q, and magnetic flux ϕ. Also, q × φ = action and q/φ = 1/resistance are known. These results of classical physics suggests to look into the corresponding quantum aspects of q and ϕ (and also of q and φ (and also of h): The electric charge occurs exclusively in elementary charges e, whereas the magnetic flux can have any value; in specific situations, however, in superconductors of type II at very low temperatures, ϕ appears quantized in the form of fluxons (Abrikosov vortices). And h leads, of course, to the Planck quantum h. Thus, one is directed to superconductivity and, because of the resistance, to the quantum Hall effect. In this way, the Josephson and the quantum Hall effects come into focus quite naturally. One goal is to determine the behavior of the fundamental constants in special and in general relativity.
Externe Organisation(en): Universität zu Köln
Universität Bremen
Typ: Artikel
Journal: Annalen der Physik
Band: 531
ISSN: 0003-3804
Publikationsdatum: 05.2019
Publikationsstatus: Veröffentlicht
Peer-reviewed: Ja
ASJC Scopus Sachgebiete: Allgemeine Physik und Astronomie
Elektronische Version(en): https://doi.org/10.1002/andp.201800407 (Zugang: Unbekannt)

BibTeX

@article{2f5c0bf0055d4307910916823eda25c6,
title = "Physical Dimensions/Units and Universal Constants: Their Invariance in Special and General Relativity",
abstract = "The theory of physical dimensions and units in physics is outlined. This includes a discussion of the universal applicability and superiority of quantity equations. The International System of Units (SI) is one example thereof. By analyzing mechanics and electrodynamics, it naturally leads one, besides the dimensions of length and time, to the fundamental units of action h, electric charge q, and magnetic flux ϕ. Also, q × φ = action and q/φ = 1/resistance are known. These results of classical physics suggests to look into the corresponding quantum aspects of q and ϕ (and also of q and φ (and also of h): The electric charge occurs exclusively in elementary charges e, whereas the magnetic flux can have any value; in specific situations, however, in superconductors of type II at very low temperatures, ϕ appears quantized in the form of fluxons (Abrikosov vortices). And h leads, of course, to the Planck quantum h. Thus, one is directed to superconductivity and, because of the resistance, to the quantum Hall effect. In this way, the Josephson and the quantum Hall effects come into focus quite naturally. One goal is to determine the behavior of the fundamental constants in special and in general relativity.",
keywords = "physical dimensions, relativistic invariance, SI, speed of light, units, universal constants",
author = "Hehl, {Friedrich W.} and Claus L{\"a}mmerzahl",
note = "Funding information: The authors would like to thank the organizers of the Wilhelm and Else Heraeus workshop for the invitation: to Klaus Blaum (Heidelberg), to Dmitry Budker (Mainz), and to Andrey Surzhykov (Braunschweig). F.W.H. is most grateful to Yuri Obukhov (Moscow) and Yakov Itin (Jerusalem) for past collaborations on the issue of physical dimensions. The authors also acknowledge very helpful remarks by Jens Boos (Edmonton), Alberto Favaro (London), Michael Krystek (Berlin), James Nester (Chung-li), and Volker Perlick (Bremen). And last, but not least, the authors thank Joachim Ullrich (Braunschweig) for useful hints and interesting discussions and two anonymous referees for their careful evaluations. C.L. acknowledges support of the DFG-funded Research Training Group 1620 “Models of Gravity” and of the Collaborative Research Center (SFB) 1128 “geo-Q” and 1227 “DQ-mat.” This article is part of the Special Issue on The Revised SI: Fundamental Constants, Basic Physics and Units, highlighting the revision and redefinition of the International System of Units (SI) to come into effect in May 2019. The authors would like to thank the organizers of the Wilhelm and Else Heraeus workshop for the invitation: to Klaus Blaum (Heidelberg), to Dmitry Budker (Mainz), and to Andrey Surzhykov (Braunschweig). F.W.H. is most grateful to Yuri Obukhov (Moscow) and Yakov Itin (Jerusalem) for past collaborations on the issue of physical dimensions. The authors also acknowledge very helpful remarks by Jens Boos (Edmonton), Alberto Favaro (London), Michael Krystek (Berlin), James Nester (Chung-li), and Volker Perlick (Bremen). And last, but not least, the authors thank Joachim Ullrich (Braunschweig) for useful hints and interesting discussions and two anonymous referees for their careful evaluations. C.L. acknowledges support of the DFG-funded Research Training Group 1620 ?Models of Gravity? and of the Collaborative Research Center (SFB) 1128 ?geo-Q? and 1227 ?DQ-mat.? This article is part of the Special Issue on The Revised SI: Fundamental Constants, Basic Physics and Units, highlighting the revision and redefinition of the International System of Units (SI) to come into effect in May 2019.",
year = "2019",
month = may,
doi = "10.1002/andp.201800407",
language = "English",
volume = "531",
journal = "Annalen der Physik",
issn = "0003-3804",
publisher = "Wiley-Blackwell",
number = "5",
}