Maximum Time and Distance needed for Pair Production inside Atom, Analytical and Theoretical

S.H. Dhobi¹ , M.D. J. Rangrej² , U. Patel³ , N.B. Shrestha⁴ , S.K. Sharma⁵

Section:Research Paper, Product Type: Journal-Paper
Vol.8 , Issue.1 , pp.16-19, Feb-2020

CrossRef-DOI:   https://doi.org/10.26438/ijsrpas/v8i1.1619

Online published on Feb 28, 2020

Copyright © S.H. Dhobi, M.D. J. Rangrej, U. Patel, N.B. Shrestha, S.K. Sharma . This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.
 

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Abstract :
In pair production, particle and antiparticle are generated when energy form mass and mass form dipole and then separation take place in stronger nuclear filed. After the formation of mass, it goes on oscillation and oscillation causes the dipole creation on mass which further goes on separation from each other as and moreover the forces F32>>F31 . These two component play major role for the separation of the masses in oscillation time having frequency (f). Also with the help of size of nucleus and atom we calculate the maximum distance and maximum time for pair production 9.99 x 10-11m and 3.33 x 10-19s, respectively.

Key-Words / Index Term :
Particle and Antiparticle, Oscillation, Dipole creaion, Maxium Distance , Maximum Time etc

References :
[1] L. Roszkowski, “Introduction to PHY008: Atomic and Nuclear Physics”, p7, 2009/2010.
[2] M. Ferrario, M. Migliorati, and L. Palumbo, “Space Charge Effects”, Proceedings of the CAS-CERN Accelerator School: Advanced Accelerator Physics, p331, 2014. Edited by W. Herr.
[3] K. Wiesemann, “A Short Introduction to Plasma Physics”, AEPT, Ruhr-Universität Bochum, Germany p4-5.
[4] A. Lawncizak and V. Asbrink, “On the 1932 Discovery of the Positron”, Royal Institute of Technology, SA104X Degree Project in Engineering Physics, First Level, Stockholm, Sweden, p10, 2014.
[5] W.S. Hwash, R. Yahaya, S. Radiman, “Effect of Core Deformation on 17B Halo Nucleus”, Physics of Atomic Nuclei, Vol.77, Iss. 3, p275–281, 2014.
[6] A. Ozawa, T. Kobayashi, H. Sato and et al., “Interaction cross sections and radii of the mass number A=17 isobar (17N, 17F, and 17Ne)”, Physics Letters B, Vol.334, Iss.1–2, p18-22, 1994.
[7] M.A. Arrizabalaga, “Experimental Methods to Measure Nuclear Radii”, Física Nuclear Etsii, p4-17, 1993-94.
[8] E. Jiménez, N. Recalde and E.J. Chacón, “Extraction of the Proton and Electron Radii from Characteristic Atomic Lines and Entropy Principles”, Entropy, Vol.19, Iss.293, p12, 2017.
[9] Physics 231, “Electric Charges, Forces, and Fields”, p21, 2008.
[10] PHY 2049, “Chapter 22: Electrostatic Force and Electric Charge”, p7.
[11] J.D. Cresser, “The Special Theory Of Relativity: Lecture Notes Prepared”, Macquarie University, Sydeny, p.29, 2003.
[12] J. D. Cresser, “Lecture Notes on Special Relativity”, Macquarie University Sydney, pp.38, August 18, 2005.
[13] P. Harris, “Lecture Note: Special Relativity”, University of Sussex, pp.67-68.
[14] S.H. Dhobi, M.D.J. Rangrej, G.P. Adhikari, and M.N. Upadhyay,“Dipole and Mass Formation are two Phenomena Causing Formation of Particle and Antiparticle in Pair Production Phenomena”, International Journal of Scientific Research in Physics and Applied Sciences, Vol.7, Iss.6, p16, 2019.
[15] D.C. Ghosh and R. Biswas, “Theoretical Calculation of Absolute Radii of Atoms and Ions. Part 1: The Atomic Radii”, International Journal of Molecular Sciences, Vol. 3, p92, 2002.
[16] Eric Muller – Exploratorium, Scaling an Atom Nothing Matters, p1-2, 2002.