New Method for Determining the Electron Streams in the Metals from the Measured Flows of Scattered Primary Radiation

P.M. Kosianov

doi:10.4028/www.scientific.net/MSF.870.735

Paper Titles

Trends and Problems of Biofuel Market Development in Kazakhstan
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Sonochemistry Effects Influence on the Adjustments of Raw Materials and Finished Goods Properties in Food Production
p.691

Modeling of Potato Convenience of Exposure Effects of Ultrasound
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Effects of the Sonochemistry in the Rheology of Food Media
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Modern Technological Possibilities of the Environmental Safety of Food Production
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Application of Intelligent Technology in Functional Materials Quality Control
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Calculation of Metalwork Life with Allowance for Cyclic Degradation of Material in Operation
p.725

The Technology of the Near-Field Interference Microwave Sensing
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New Method for Determining the Electron Streams in the Metals from the Measured Flows of Scattered Primary Radiation
p.735

HomeMaterials Science ForumMaterials Science Forum Vol. 870New Method for Determining the Electron Streams in...

New Method for Determining the Electron Streams in the Metals from the Measured Flows of Scattered Primary Radiation

Abstract:

The paper examines the results of theoretical and experimental studies of different interaction of ionizing emission photons with substances, in particular, the photo effect and the Compton scattering of these photons. The paper substantiates a new method of determining the recoil electrons number - the photoelectrons number ratio. The results of certain measurements are presented. The analysis of the results showed that there are noticeable divergences between the theoretical calculations and the experimental data.

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Periodical:

Materials Science Forum (Volume 870)

Pages:

735-740

DOI:

https://doi.org/10.4028/www.scientific.net/MSF.870.735

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Online since:

September 2016

Authors:

P.M. Kosianov*

Keywords:

Compton Scattering, Gamma Emissions, Incoherently Scattered of X-Ray, Photo Effect, Ratio of the Intensities of the Characteristic, Ratio of the Number of Recoil Electrons to the Number of Photoelectrons

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