Showing posts with label Super heavy element. Show all posts
Showing posts with label Super heavy element. Show all posts

Monday, 7 September 2020

On the role of nuclear quantum gravity in understanding nuclear stability range of Z = 2 to 118

 

  • UVS Seshavatharam
    Honorary faculty, I-SERVE, Survey no-42, Hitech city, Hyderabad-84,Telangana, India
  • S Lakshminarayana
    Department of Nuclear Physics, Andhra University, Visakhapatnam-03, Andhra Pradesh, India
Keywords: Four gravitational constants, Compound reduced Planck’s constant, Nuclear elementary charge, Strong coupling constant, Nuclear binding energy, Nuclear stability limits, Super heavy element

Abstract

To understand the mystery of final unification, in our earlier publications, we proposed two bold concepts: 1) There exist three atomic gravitational constants associated with electroweak, strong and electromagnetic interactions. 2) There exists a strong elementary charge in such a way that its squared ratio with normal elementary charge is close to reciprocal of the strong coupling constant. In this paper we propose that, ℏc can be considered as a compound physical constant associated with proton mass, electron mass and the three atomic gravitational constants. With these ideas, an attempt is made to understand nuclear stability and binding energy. In this new approach, with reference to our earlier introduced coefficients k = 0.00642 and f = 0.00189, nuclear binding energy can be fitted with four simple terms having one unique energy coefficient. The two coefficients can be addressed with powers of the strong coupling constant. Classifying nucleons as ‘free nucleons’ and ‘active nucleons’, nuclear binding energy and stability can be understood. Starting from , number of isotopes seems to increase from 2 to 16 at and then decreases to 1 at For Z >= 84, lower stability seems to be, Alower=(2.5 to 2.531)Z.

 

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How to Cite
UVS Seshavatharam; S Lakshminarayana. On the Role of Nuclear Quantum Gravity in Understanding Nuclear Stability Range of Z = 2 to 118. J. Nucl. Phy. Mat. Sci. Rad. A. 2020, 7, 43-51.

 

 

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