Application of a New Mass-Energy Concept in the Computation of Atomic Nuclear Masses
Main Article Content
Abstract
In most literatures and scientific extrapolations, the Bethe-Weizsacker’s mass formula is dependent on Einstein’s relativistic mass-energy theory for calculations of nuclear masses, but the relativistic energy converting factor (speed of light) is only attributed to massless particle. Therefore, the method employed involves the conversion of the binding energy fitting coefficients by krane from mega electron volt to unified atomic mass unit (u) using Einstein relativistic mass-energy theory, Bahjat mass-energy relation and our new mass-energy concept. A close correlation can be observed between the calculated masses of light, medium and heavy nuclei using the relativistic mass-energy theory (mc2), our new mass energy concept (mvc) and the experimentally measured mass. The Bahjat mass-energy relation (mbc) is underestimated compared to our new mass energy concept. Therefore, any particle with mass greater than zero would travel with speed less than the speed of light. Hence the relation, E = mc2, needs to be modified. It would therefore be more precise to apply the mass energy concept, E = mvc, for a mass particle. This is the reason why the Beth-Weizsacker’s semi empirical mass formula shows a closer result to the experimental results, for masses of nuclei, when computation is done with our new mass -energy concept.
Downloads
Article Details
References
Taghreed, A. J.Y & Firas M. H. (2019) Calculation of the Stopping power of alpha particles and its range in bone tissue. International Journal of Research –GRANTHAALAYAH. 7(4), 315-320Isabel, A., Pablo, D. V., & Rafael, G.M. (2021) Calculated energy loss of swift light ions in platinum and gold: importance of the target electronic excitation spectrum. arXiv:2111.13968v1El-Ghossain, M. O. (2017) Calculations of Stopping Power, And Range Of Electrons Interaction With Different Material And Human Body Parts. International journal of scientific and technology research, 6 (1), 114 -118Ahlam S. Almutairi1 &Khalda T. Osman (2022) Mass Stopping Power and Range of Protons in Biological Human Body Tissues (Ovary, Lung and Breast). International Journal of Medical Physics, Clinical Engineering and Radiation Oncology. 11, 48-59Ahmed, I., Nowrin, H. and Dhar, H. (2020) Stopping Power and Range Calculations of Protons in Human Tissues. Baghdad Science Journal, 17, Article No. 1223Anthony K.S.A., Godsway B.K., Nayaaba R.A., & Eric M.N.(2017) A Theoretical Study of Stopping Power and Range For Low Energy <3.0Mev (Protons In Aluminum, Germanium, Lead, Gold and Copper Solid Materials. Open Science Journal. 2 (2)Berger, M. J., Inokuti, M., Andersen, H. H., Bichsel, H., Powers, D., Seltzer, S. M., Thwaites, D., Watt, D. E. (1993) Report 49, J ICRU os25 (2) NP–NP. Oxford Academic.Doré, D., Farget, F., Lecolley, F.R., Lehaut, G., Materna, T., Pancin, J., Panebianco, S., & Papaevangelou, T. (2014). A new tool for fission fragment characterization. NuclearData Sheets, 119, 346-348. doi:https://doi.org/10.1016/j.nds.2014.08.095.Ngari, A. Z., Ngadda, Y.H. & Hassan, M. (2023) Calculation of Electron Stopping Power in Some Material Targets Using New Mass-Energy Concept. NIPES Journal of Science and Technology Research 5(2) pp. 1-8ISSN-2682-5821Annamalai, C. & Antonio, M. (2023) Mass-Energy Equivalence derived from Newtonian mechanics. Journal of Engineering and Exact Sciences, 9 (8), Page 1– 4. ISSN: 2527-1075, ISSN: 2446-9416, doi: 10.18540/jcecvl9iss8pp15963-01eAnnamalai, C. (2022) The Mass-Energy Equivalence, SSRN Electronic journals. https://www.doi.org/10.33774/coe-2023-ck6jr-v2Annamalai, C. (2023a) The Einstein’s Mass-Energy Equivalence and the Relativistic Mass and Momentum derived from the Newton’s Second Law of Motion. CoE, Cambridge University Press. https://www.doi.org/10.33774/coe-2023-ck6jr-v2.Annamalai, C. (2023g) Mass-Energy Equivalence derived from Work and Kinetic Energy. Zenoto. https://dx.doi.org/10.5281/zenodo.8015743. Annamalai, C. (2023h) A Mathematical Approach to the Momentum Equations of Massless Photon and Particle with Relativistic Mass. engrXiv. https://doi.org/10.31224/3030.Perez, A. & Ribisi, S. (2022) Energy-mass equivalence from Maxwell equations. American Journal of Physics, 90(4), Page 304-313. https://doi.org/10.1119/10.0009156 Bahjat R. J. Muhyedeen (2008) On Heuristic Viewpoints Concerning the Mass, Energy and Light Concepts in Quantum Physics. European Journal of Scientific Research. 22 (4), 584-60