MIXING IN TI/STEEL SYSTEM UNDER HIGH-INTENSITY PULSED ION BEAM IMPACT

N. N. Cherenda; V. I. Shymanski; A. Ya Leyvi; V. V. Uglov; A. P. Yalovets; H. W. Zhong; S. J. Zhang; X. Y. Le; G. E. Remnev; S. Y. Dai

doi:10.1615/HighTempMatProc.2021042087

MIXING IN TI/STEEL SYSTEM UNDER HIGH-INTENSITY PULSED ION BEAM IMPACT

N. N. Cherenda^*
, V. I. Shymanski
, A. Ya Leyvi
, V. V. Uglov
, A. P. Yalovets
, H. W. Zhong
, S. J. Zhang
, X. Y. Le
, G. E. Remnev
, S. Y. Dai

^*Corresponding author for this work

School of Physics

Belarusian State University
South Ural State University
Beihang University
Tomsk Polytechnic University
Dalian University of Technology

Research output: Contribution to journal › Article › peer-review

4 Scopus citations

Abstract

The structure, phase, element composition, and surface morphology of Ti/steel systems subjected to the treatment of high-intensity pulsed ion beams were investigated in this work. Numerical simulation, scanning electron microscopy, energy dispersion x-ray microanalysis, and x-ray diffraction analysis were used as investigation techniques. Ion beam impact with a Ti/steel system was accompanied with surface layer ablation, melting, mixing, and generation of shock waves. The findings showed that mixing efficiency was dependent on the power of the ion beam and the number of pulses. The synthesis of the mixed layer with a thickness of ~ 2 μm containing FeTi and Fe₂ Ti phases was observed just after one pulse of treatment, with the energy absorbed by the surface layer of 3.1 J/cm². Ti concentration in the surface layer, as well as intermetallide volume fraction, was dependent on the number of pulses. Growth of the pulse number led to more uniform distribution of Ti in the mixed layer. The synthesized surface layer possessed increased microhardness.

Original language	English
Pages (from-to)	1-16
Number of pages	16
Journal	High Temperature Material Processes
Volume	26
Issue number	1
DOIs	https://doi.org/10.1615/HighTempMatProc.2021042087
State	Published - 2022

Keywords

ablation
high-intensity pulsed ion beam
hydrogen storage
intermetallide
ion beam mixing
shock waves

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10.1615/HighTempMatProc.2021042087

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@article{356d9d5f1fd84380a71082839997661f,

title = "MIXING IN TI/STEEL SYSTEM UNDER HIGH-INTENSITY PULSED ION BEAM IMPACT",

abstract = "The structure, phase, element composition, and surface morphology of Ti/steel systems subjected to the treatment of high-intensity pulsed ion beams were investigated in this work. Numerical simulation, scanning electron microscopy, energy dispersion x-ray microanalysis, and x-ray diffraction analysis were used as investigation techniques. Ion beam impact with a Ti/steel system was accompanied with surface layer ablation, melting, mixing, and generation of shock waves. The findings showed that mixing efficiency was dependent on the power of the ion beam and the number of pulses. The synthesis of the mixed layer with a thickness of \textasciitilde{} 2 μm containing FeTi and Fe2 Ti phases was observed just after one pulse of treatment, with the energy absorbed by the surface layer of 3.1 J/cm2. Ti concentration in the surface layer, as well as intermetallide volume fraction, was dependent on the number of pulses. Growth of the pulse number led to more uniform distribution of Ti in the mixed layer. The synthesized surface layer possessed increased microhardness.",

keywords = "ablation, high-intensity pulsed ion beam, hydrogen storage, intermetallide, ion beam mixing, shock waves",

author = "Cherenda, \{N. N.\} and Shymanski, \{V. I.\} and Leyvi, \{A. Ya\} and Uglov, \{V. V.\} and Yalovets, \{A. P.\} and Zhong, \{H. W.\} and Zhang, \{S. J.\} and Le, \{X. Y.\} and Remnev, \{G. E.\} and Dai, \{S. Y.\}",

note = "Publisher Copyright: {\textcopyright} 2022 by Begell House, Inc. www.begellhouse.com.",

year = "2022",

doi = "10.1615/HighTempMatProc.2021042087",

language = "英语",

volume = "26",

pages = "1--16",

journal = "High Temperature Material Processes",

issn = "1093-3611",

publisher = "Begell House Inc.",

number = "1",

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TY - JOUR

T1 - MIXING IN TI/STEEL SYSTEM UNDER HIGH-INTENSITY PULSED ION BEAM IMPACT

AU - Cherenda, N. N.

AU - Shymanski, V. I.

AU - Leyvi, A. Ya

AU - Uglov, V. V.

AU - Yalovets, A. P.

AU - Zhong, H. W.

AU - Zhang, S. J.

AU - Le, X. Y.

AU - Remnev, G. E.

AU - Dai, S. Y.

PY - 2022

Y1 - 2022

N2 - The structure, phase, element composition, and surface morphology of Ti/steel systems subjected to the treatment of high-intensity pulsed ion beams were investigated in this work. Numerical simulation, scanning electron microscopy, energy dispersion x-ray microanalysis, and x-ray diffraction analysis were used as investigation techniques. Ion beam impact with a Ti/steel system was accompanied with surface layer ablation, melting, mixing, and generation of shock waves. The findings showed that mixing efficiency was dependent on the power of the ion beam and the number of pulses. The synthesis of the mixed layer with a thickness of ~ 2 μm containing FeTi and Fe2 Ti phases was observed just after one pulse of treatment, with the energy absorbed by the surface layer of 3.1 J/cm2. Ti concentration in the surface layer, as well as intermetallide volume fraction, was dependent on the number of pulses. Growth of the pulse number led to more uniform distribution of Ti in the mixed layer. The synthesized surface layer possessed increased microhardness.

AB - The structure, phase, element composition, and surface morphology of Ti/steel systems subjected to the treatment of high-intensity pulsed ion beams were investigated in this work. Numerical simulation, scanning electron microscopy, energy dispersion x-ray microanalysis, and x-ray diffraction analysis were used as investigation techniques. Ion beam impact with a Ti/steel system was accompanied with surface layer ablation, melting, mixing, and generation of shock waves. The findings showed that mixing efficiency was dependent on the power of the ion beam and the number of pulses. The synthesis of the mixed layer with a thickness of ~ 2 μm containing FeTi and Fe2 Ti phases was observed just after one pulse of treatment, with the energy absorbed by the surface layer of 3.1 J/cm2. Ti concentration in the surface layer, as well as intermetallide volume fraction, was dependent on the number of pulses. Growth of the pulse number led to more uniform distribution of Ti in the mixed layer. The synthesized surface layer possessed increased microhardness.

KW - ablation

KW - high-intensity pulsed ion beam

KW - hydrogen storage

KW - intermetallide

KW - ion beam mixing

KW - shock waves

UR - https://www.scopus.com/pages/publications/85128851013

U2 - 10.1615/HighTempMatProc.2021042087

DO - 10.1615/HighTempMatProc.2021042087

M3 - 文章

AN - SCOPUS:85128851013

SN - 1093-3611

VL - 26

SP - 1

EP - 16

JO - High Temperature Material Processes

JF - High Temperature Material Processes

IS - 1

ER -

MIXING IN TI/STEEL SYSTEM UNDER HIGH-INTENSITY PULSED ION BEAM IMPACT

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Keywords

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