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

Journal of Nuclear Physics, Material Sciences, Radiation and Applications Pub Date : 2020-03-02 DOI:10.15415/jnp.2019.71005

U. Seshavatharam, S. Lakshminarayana

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引用次数: 5

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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核量子引力在理解Z = 2 ~ 118核稳定范围中的作用

为了理解最终统一的奥秘，在我们早期的出版物中，我们提出了两个大胆的概念:1)存在与电弱、强和电磁相互作用相关的三个原子引力常数。2)存在一种强基本电荷，其与正常基本电荷的平方比接近于强耦合常数的倒数。在本文中，我们提出，可以把c看作与质子质量、电子质量和三个原子引力常数有关的复合物理常数。有了这些想法，就可以尝试理解核的稳定性和结合能。在这个新方法中，参考我们之前引入的系数k = 0.00642和f = 0.00189，核结合能可以用四个具有唯一能量系数的简单项来拟合。这两个系数可以用强耦合常数的幂来表示。将核子分为“自由核子”和“活动核子”，可以理解核子的结合能和稳定性。从，同位素的数量似乎从2个增加到16个，然后减少到1个，对于Z >= 84，稳定性较低，Alower=(2.5 ~ 2.531)Z。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Journal of Nuclear Physics, Material Sciences, Radiation and Applications

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