The Processes of Violent Disintegration and Natural Creation of Matter in the Universe

Weitter Duckss


This article completes the circle of presenting the process of the constant growth of objects and systems and the topics to complete it consist of the visible matter violent disintegration and its re-creation inside the Universe. A constant process of the visible matter disintegration is presented as the end of the process, the proportions of which are gigantic, and the creation of the visible matter as the beginning of it. The disintegration of particles disturbs the balance of the Universe's wholeness; despite the enormous loss of the visible matter, the Universe is constantly growing. After having postponed it for a while, this article discusses the age of objects and the Universe as a consequence of the process of the constant matter growth. The acquired results are completely different from those, offered by the renowned experts of the time.


disintegration of matter; particle formation; the age of the Universe

Full Text:



Bardyn, A. (2017). Carbon-rich dust in comet 67P/Churyumov-Gerasimenko measured by COSIMA/Rosetta. Monthly Notices of the Royal Astronomical Society, S712–S722.

Duckss, W. (2019). Učinci Rotacije Oko Osi Na Zvijezde, Galaksiju I Rotaciju Svemira. International Journal of Sciences, 76-97.

Duckss, W. (2019). When Occurring Conditions for the Emergence of Life and a Constant Growth, Rotation and its Effects, Cyclones, Light and Redshift in Images. International Journal of Sciences, 34-46.

Duckss, W. (2019). Why do Hydrogen and Helium Migrate from Some Planets and Smaller Objects?. Intellectual Archive.

Duckss, W. (2018). The Processes Which Cause the Appearance of Objects and Systems. American Journal of Astronomy and Astrophysics,72-80.

Ge, R. (2018). A 4463 Ma apparent zircon age from the Jack Hills (Western Australia) resulting from ancient Pb mobilization. Geology.

Helmenstine, A. M. (2018), What Is the Sun Made Of? Table of Element Composition.

John S. M. (2019). Nebula astronomy, Encyclopædia Britannica.

John, E. (1979). A New Sun: The Solar Results From Skylab, by, NASA SP-402. Stanford Solar Center.

Lagzi, I., Mészáros, R., Gelybó, G., Leelőssy, Á. (2013). Atmospheric Chemistry. Eötvös Loránd University.

Niemann, H. B. et al. (2005). The abundances of constituents of Titan's atmosphere from the GCMS instrument on the Huygens probe. Nature, 779–784.

Samuel, A. F. (2019). On the Performance of Transmuted Logistic Distribution: Statistical Properties and Application. Budapest International Research in Exact Sciences (BirEx) Journal, 26–34.

Sedic, S. (2016). Why there are differences in structure of the objects in our system. International Journal of Scientific & Engineering Research, 408-422.

Street, J. C., & Stevenson, E. C. (1937). New Evidence for the Existence of a Particle of Mass Intermediate Between the Proton and Electron. Physical Review Journals Archive.

Zigta, B. (2019). Thermal Radiation, Chemical Reaction and Viscous Dissipation Effects on Unsteady MHD Flow of Viscoelastic Fluid Embedded in a Porous Medium. Budapest International Research in Exact Sciences (BirEx) Journal, 35-57.

Williams, D. R. (2010). Mars Fact Sheet. National Space Science Data Center. NASA.

Williams, D. R. (2016). Saturn Fact Sheet. NASA.

Yukawa, H. (1935). On the Interaction of Elementary Particles.


Article Metrics

Abstract view : 312 times
PDF - 157 times


  • There are currently no refbacks.

Creative Commons License
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.

Creative Commons License
This work is licensed under a Creative Commons Attribution-ShareAlike 4.0 International License.


Statcounter for Budapest International Research in Exact Sciences (BirEx Journal)