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Bremsstrahlung Cross Sections in Ceramic Compounds at Incident Electron Energies (10 kev, 20 kev and 30kev)

Published on September 2016 by Suhansar Jit Sharma, Doordarshi Singh, Tajinder Singh
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International Conference on Advances in Emerging Technology
Foundation of Computer Science USA
ICAET2016 - Number 9
September 2016
Authors: Suhansar Jit Sharma, Doordarshi Singh, Tajinder Singh
0d202d84-eaa5-48fa-a8fc-3ac464662076

Suhansar Jit Sharma, Doordarshi Singh, Tajinder Singh . Bremsstrahlung Cross Sections in Ceramic Compounds at Incident Electron Energies (10 kev, 20 kev and 30kev). International Conference on Advances in Emerging Technology. ICAET2016, 9 (September 2016), 1-4.

@article{
author = { Suhansar Jit Sharma, Doordarshi Singh, Tajinder Singh },
title = { Bremsstrahlung Cross Sections in Ceramic Compounds at Incident Electron Energies (10 kev, 20 kev and 30kev) },
journal = { International Conference on Advances in Emerging Technology },
issue_date = { September 2016 },
volume = { ICAET2016 },
number = { 9 },
month = { September },
year = { 2016 },
issn = 0975-8887,
pages = { 1-4 },
numpages = 4,
url = { /proceedings/icaet2016/number9/25931-t132/ },
publisher = {Foundation of Computer Science (FCS), NY, USA},
address = {New York, USA}
}
%0 Proceeding Article
%1 International Conference on Advances in Emerging Technology
%A Suhansar Jit Sharma
%A Doordarshi Singh
%A Tajinder Singh
%T Bremsstrahlung Cross Sections in Ceramic Compounds at Incident Electron Energies (10 kev, 20 kev and 30kev)
%J International Conference on Advances in Emerging Technology
%@ 0975-8887
%V ICAET2016
%N 9
%P 1-4
%D 2016
%I International Journal of Computer Applications
Abstract

Numerical bremsstrahlung cross sections for different ceramic compounds like Alumina (Al2O3), beryllia (BeO), ceria (CeO), Zirconia (ZrO2) were calculated by using Zmod of metallic compounds at different incident electron energies (10 keV,20 keV and 30 keV) in the photon energy regions of energy (1-10 keV,1-20 keV and 1-30 keV). The cross sections were calculated by using Elwert corrected (non relativistic) Bethe Heitler (1934) theory for ordinary bremsstrahlung (OB), modified Elwert factor (relativistic) Bethe Heitler theory for OB and modified Elwert Factor(relativistic) Bethe Heitler theory which includes the polarization Bremsstrahlung (PB ) into OB given by Avdonia and Pratt (1999). The effect of effective atomic number of the metallic compounds on the bremsstrahlung cross sections is studied. Comparing the results of above theories the dependence of PB and OB on energy of incident electrons and the energy of emitted photon is studied. The results clearly indicate the importance of PB, particularly in the studied energy regions.

References
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Index Terms

Computer Science
Information Sciences

Keywords

Ordinary Bremsstrahlung Polarization Bremsstrahlung Ceramic Compounds Bremsstrahlung Cross Sections