The Significance of Shear Stress in Cosmology

John A. T. Bye

Full Article - PDF Review History

Published: 2022-12-21

Page: 176-181

Issue: 2022 - Volume 4 [Issue 1]

The Significance of Shear Stress in Cosmology

Full Article - PDF Review History

Published: 2022-12-21

Page: 176-181

Issue: 2022 - Volume 4 [Issue 1]

John A. T. Bye *

School of Geography, Earth and Atmospheric Sciences, The University of Melbourne, Victoria 3010, Australia.

*Author to whom correspondence should be addressed.

Abstract

The concept of shear stress forms a fundamental base for meteorology and oceanography, which is the heritage of classical physics. In this paper, we show by well understood physical reasoning that it is also fundamental to cosmology although this link has not been previously recognised. The key physical model is that of the sea surface where two fluids (air and water) of high density contrast interact giving rise to a constant shear stress layer and wave breaking.

In cosmology, we show that two analogous, equal and opposite stress layers, due respectively to the formation of galaxies on the large scale and to their destruction by black holes on the small scale, constitute the physical model for the Universe, in which the mean shear stress is zero. The consequences of this condition for the expanding Universe are shown in a simple model. Two comparative images are also presented which illustrate the similarity between stress fields observed in a laboratory experiment and in the cosmos.

Keywords: Shear stress, net-zero cosmic stress, the evolving Universe

How to Cite

Bye, John A. T. 2022. “The Significance of Shear Stress in Cosmology”. International Astronomy and Astrophysics Research Journal 4 (1):176-81. https://journaliaarj.com/index.php/IAARJ/article/view/74.

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References

Bye JAT. Wind-driven circulation in unstratified lakes. Limnol. Oceanogr. 1965;10:451-458.

Bye JAT. Momentum exchange at the sea surface by wind stress and understress. Quart. J. Roy. Met. Soc. 1986;112:501-510.

Proudman J. Dynamical oceanography. Methuen. (New York). 1953:407.

Bye JAT. The adjunct force of gravity. Intl. Astron. and Astrophys. Res. J. 2021a;3(1): 1-7.

Newton I. Philosophiae naturalis principia mathematica. Lib,I, Sec. 11,12; Lib. III, Prop.18,19,20. (London); 1687.

Jones ISF, Toba Y. Wind stress over the ocean. 2nd Ed. Cambridge Univ. Press (Cambridge). 2008:307.

Bye JAT. Stress: The forgotten gravitational force. Intl. Astron. and Astrophys. Res. J. 2021b;3(3):27-32.

Bye JAT, Babanin A. Wave generation by wind. In Encyclopedia of Ocean Sciences 3rd Ed. Cochran JK, Bokuniewicz HJ. (eds.). 2019:707-712.

Lorenz EN. The Essence of Chaos. The University of Washington Press (The University of Washington). 1993;227.

Bye JAT, Ghantous MP. Observations of Kelvin-Helmholtz instability at the air-water interface in a circular domain. Phys. Fluids. 2012;24:0321101-4.

ESA/Webb, NASA & CSA 2022. J. Lee and the PHANGS-JWST Team.

Weaver D/Villard R et al. Mystery of the Universe’s expansion rate widens with new hubble data. National Aeronautics and Space Administration; 2019.

Available:https://www.nasa.gov/feature/goddard/2019/mystery-of-the-universe

Observable Universe – Wikipedia.

Available:https//en- wikipedia.org/wiki/Observable_universe

Big Bang – Wikipedia.

Available:https//en-wikipedia.org/wiki/Big_Bang