Computer Simulation of Vacancy Clusters Distribution by Depth in Molybdenum Irradiated by Alpha Particles

Anatoliy I. Kupchishin; Nataliya A. Voronova; Tatyana A. Shmygaleva; Alexander A. Kupchishin

doi:10.4028/www.scientific.net/KEM.781.3

Paper Titles

Preface

Computer Simulation of Vacancy Clusters Distribution by Depth in Molybdenum Irradiated by Alpha Particles
p.3

Technological Features of the Thick Tin Film Deposition by with Magnetron Sputtering Form Liquid-Phase Target
p.8

Radiation Defects in HCC Materials at Atomic Spatial Level
p.14

Acquiring MIS Structures Based on Bа_0.8Sr_0.2TiО₃Ferroelectric Films and their Properties
p.20

Dose Dependences of the Mechanical Strength of Polymer Materials
p.25

Investigation of Thermal Explosion Formation in Heterogeneous Systems
p.30

Effect of Temperature on the Magnetic Permeability of Hexagonal Ferrites
p.36

Influence of Morphology of the Press Powder Particles and Thermal Annealing on the Structure and Microhardness of Palladium Obtained by Solid-Phase Sintering
p.41

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Computer Simulation of Vacancy Clusters Distribution by Depth in Molybdenum Irradiated by Alpha Particles

Abstract:

Computer simulation of vacancy clusters distribution by depth in molybdenum irradiated by alpha particles within Cascade probability method has been carried out. Cascade probability functions have been calculated taking into account energy losses for alpha particles in molybdenum and depending on number of interactions and depth of particles penetration. Microhardness comparison of calculations and modified experimental data show their satisfactory fit.

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Key Engineering Materials (Volume 781)

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3-7

DOI:

https://doi.org/10.4028/www.scientific.net/KEM.781.3

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September 2018

Authors:

Anatoliy I. Kupchishin*, Nataliya A. Voronova, Tatyana A. Shmygaleva, Alexander A. Kupchishin

Keywords:

Algorithm, Calculation, Cascade Function, Concentration, Ion, Modeling, Nanoclusters, Probability Function, Vacancy Clusters

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