Application of Binary Encounter Approximation and Electron Impact on Ionization of Atoms

Authors

  • Suresh Prasad Gupta Patan Multiple Campus, TU
  • Raju Khanal Central Department, TU, Kirtipur

DOI:

https://doi.org/10.3126/pragya.v8i01.42432

Keywords:

Binary encounter approximation, Single and Double ionization, Ionization cross section, HF momentum distribution function, Vrien’s accurate expression of energy transfer

Abstract

Semi-classical binary encounter approximation has been used for theoretical calculations of electron impact single ionization cross sections of Xe and Kr and double ionization of Fe atom at ground state. An accurate expression of cross section for energy transfer ΔE (σΔE) as given by Vriens and quantum mechanical Hartree-Fock velocity distributions for target electron have been used in the calculation. In the case of single ionization of Xe, 71% theoretical results lies within valid range of ratio factor less than 2 and 55% have valueless than 1.5. In the case of Kr, 97% of results have ratio factor less than 2 and 34% of results have ratio factor less than 1.1. Gryzinski and Kune model of charged particle impact double ionization of atoms found suitable for describing double ionization of atoms and ions. In the case of double ionization of Fe by electron impact 47% of results have ratio factor less than 2 and 18% of results have ratio factor 1.2. At impact 760 eV, 800 eV and 850 eV having ratio factor 1.01, 0.989 and 0.967. Major contribution in double ionization is 60.16% from (4s,3d) and 31% is from (4s,3p).

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Author Biographies

Suresh Prasad Gupta, Patan Multiple Campus, TU

Associate Professor of Physics

Raju Khanal, Central Department, TU, Kirtipur

Faculty Member of Physics

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Published

2021-12-31

How to Cite

Gupta, S. P., & Khanal, R. (2021). Application of Binary Encounter Approximation and Electron Impact on Ionization of Atoms. Patan Pragya, 8(01), 174–186. https://doi.org/10.3126/pragya.v8i01.42432

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