Study on the damage of Fe80B13Si7 alloy with different structure by high-intensity pulsed ion beam irradiation; Surface and Coatings Technology; Vol. 395

Study on the damage of Fe80B13Si7 alloy with different structure by high-intensity pulsed ion beam irradiation; Surface and Coatings Technology; Vol. 395

Podrobná bibliografie
Parent link:	Surface and Coatings Technology Vol. 395.— 2020.— [125933, 10 p.]
Korporativní autor:	Национальный исследовательский Томский политехнический университет Исследовательская школа физики высокоэнергетических процессов
Další autoři:	Guan Tong, Zhang Xiaonan, Zhang Lisong, Li Na, Li Xiaona, Wang Younian, Mei Xianxiu, Remnev G. E. Gennady Efimovich, Pavlov S. K. Sergey Konstantinovich, Uglov V. V. Vladimir Vasilievich
Shrnutí:	Title screen In this study, Fe80B13Si7 alloys with the same components but different structure, amorphous and crystal, were irradiated by high-intensity pulsed ion beams (HIPIB) with different parameters. The irradiation damage behavior of amorphous and crystal alloy by the HIPIB irradiation was studied. TEM analysis of the cross-section showed that after HIPIB irradiation, the atoms in amorphous alloy were aggregated and migrated, and the arrangement of atoms became uneven, no nanocrystal was observed. For the crystal, Fe3B, Fe3Si, Fe2B and Fe3C nanocrystals appeared besides the main structure of the a-Fe phase after HIPIB irradiation. A mass of defects appeared in the crystal. Meanwhile, XRD results showed that the lattice parameters of a-Fe phase were decreased. The effect range of the structure and defects of the crystal and the atomic arrangement of amorphous alloy by irradiation were far beyond the incident ion range. After HIPIB irradiation, the surface of amorphous alloy showed no obvious irradiation damage, and the surface of crystal showed wavy undulations. The roughness of both two alloys was increased, and the surface diffusion caused by the thermal driving and ion induction was the main mechanism of surface evolution. The decrease of the surface reflectivity of the amorphous alloy was smaller than that of the crystal. Режим доступа: по договору с организацией-держателем ресурса
Jazyk:	angličtina
Vydáno:	2020
Témata:	электронный ресурс труды учёных ТПУ high-intensity pulsed ion beam (HIPIB) Fe80B13Si7 crystal amorphous irradiation damage радиационные повреждения импульсные ионные пучки
On-line přístup:	https://doi.org/10.1016/j.surfcoat.2020.125933
Médium:	Elektronický zdroj Kapitola
KOHA link:	https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=662555

Podobné jednotky

Study on the damage of Zr63.5Cu23Al9Fe4.5 amorphous and crystalline alloys irradiated by high intensity pulsed ion beam; Journal of Alloys and Compounds; Vol. 923
Vydáno: (2022)

Study on thermal shock irradiation resistance of CoCrFeMnNi high entropy alloy by high intensity pulsed ion beam; Journal of Nuclear Materials; Vol. 559
Vydáno: (2022)

Effect on microstructure of Fe80B13Si7 metallic glass irradiated by high intensity pulsed ion beam and He ions; Surface and Coatings Technology; Vol. 449
Vydáno: (2022)

Effects on structure and properties of Zr55Al 10Cu30Ni5 metallic glass irradiated by high intensity pulsed ion beam; Applied Surface Science; Vol. 313
Vydáno: (2014)

Effect of Preliminary Irradiation of 321 Steel Substrates with High-Intense Pulsed Ion Beams on Scratch Test Results of Subsequently Deposited AlN Coatings; Coatings; Vol. 11, iss. 10
Vydáno: (2021)

Changing Mechanisms of High-Temperature Oxidation of Zr-1%Nb Alloy in Air and Steam by Surface Modification with Charged Particles; Journal of Materials Engineering and Performance; Vol. 34, iss. 13
Vydáno: (2025)

Effect on mechanics properties and microstructure of molybdenum by high intensity pulsed ion beam irradiation; Surface and Coatings Technology; Vol. 384
Vydáno: (2020)

Shielding of energy deposition by ablation of plastics under intense pulsed ion beam irradiation; Vacuum; Vol. 174
Vydáno: (2020)

Surface microstructure and phase structure of zirconia ceramics under intense pulsed ion beam irradiation; Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms; Vol. 542
Vydáno: (2023)

A method of real-time monitoring beam output stability of intense pulsed ion beam; Acta Physica Sinica; Vol. 72, iss. 17
Vydáno: (2023)

DIN 1.7035 Steel Modification with High Intensity Nitrogen Ion Implantation; Russian Physics Journal; Vol. 61, iss. 2
Vydáno: (2018)

Influence of magnetic field of a radial focusing external magnetically insulated diode on emission behavior of intense pulsed ion beam; Nuclear Instruments and Methods in Physics Research B; Vol. 537
Vydáno: (2023)

Plasma-immersion formation of high-intensity gaseous ion beams; Vacuum; Vol. 165
Vydáno: (2019)

Focusing of intense pulsed ion beam by magnetically insulated diode for material research; Surface and Coatings Technology; Vol. 384
Vydáno: (2020)

On evaporation smoothing mechanism of metal surface under the irradiation by submicrosecond ion beams; 9th International Conference on Modification of Materials with Particle Beams and Plasma Flows, Tomsk, 21-21September 2008
Autor: Bleykher (Bleicher) G. A. Galina Alekseevna
Vydáno: ()

Study of phase transformation and surface microstructure of alumina ceramic under irradiation of intense pulsed ion beam; Vacuum; Vol. 187
Vydáno: (2021)

The ablation of plastics by intense pulsed ion beam; Surface and Coatings Technology; Vol. 384
Vydáno: (2020)

Investigation of the Features of High-Intensity Implantation of Nitrogen Ions into Titanium; Journal of Surface Investigation. X-ray, Synchrotron and Neutron Techniques; Vol. 17, s. 1
Vydáno: (2023)

Surface Modification of ZrO2-3Y2O3 with Highintensity Pulsed N2+ Ion Beams; Russian Physics Journal; Vol. 63, iss. 1
Vydáno: (2020)

Ablation induced by intense pulsed ion beam and its effects on energy deposition on solid target; Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms; Vol. 461
Vydáno: (2019)

The Influence of Metal Surface Topography on Ablation Behavior During Intense Pulsed Ion Beam Irradiation; Surface Modification of Materials by Ion Beams (SMMIB-2019)
Vydáno: (2019)

Formation of nanoscale carbon structures in the surface layer of metals under the impact of high intensity ion beam; Applied Surface Science; Vol. 310
Vydáno: (2014)

Thermal field induced by intense pulsed ion beam and its possible application in thermal diffusivity measurement; Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms; Vol. 409
Vydáno: (2017)

Mixing in TI/STEEL system under High-intensity pulsed ion beam impact; High Temperature Material Processes: An International Quarterly of High-Technology Plasma Processes; Vol. 26, iss. 1
Vydáno: (2022)

Microstructure Formation and Mechanical Properties of Metastable Titanium-Based Gradient Coating Fabricated via Intense Pulse Ion Beam Melt Mixing; Materials; Vol. 16, iss. 8
Vydáno: (2023)

Spectral analysis of nanosize forms of carbon synthesized by pulsed intense ion beams; Vacuum; Vol. 89
Vydáno: (2013)

Influence of the high-power ion-beam irradiation of a hydroxyapatite target on the properties of formed calcium phosphate coatings; Journal of Surface Investigation. X-ray, Synchrotron and Neutron Techniques; Vol. 7, iss. 5
Autor: Bleykher (Bleicher) G. A. Galina Alekseevna
Vydáno: (2013)

Investigation of the effects of an intense pulsed ion beam on the surface melting of IN718 superalloy prepared with selective laser melting; Metals; Vol. 10, iss. 9
Vydáno: (2020)

The influence of ion irradiation on the properties of ceramic silicon carbide; Energy Fluxes and Radiation Effects (EFRE-2016)
Vydáno: (2016)

High-intensity pulsed ion beam focusing by its own space charge; Laser and Particle Beams; Vol. 36, iss. 4
Vydáno: (2018)

Simulation of electron field emission from the surface of ionic crystals under irradiation by pulsed electron beam; Известия вузов. Физика; Т. 55, № 11/3
Autor: Stepanov S. A. Sergey Aleksandrovich
Vydáno: (2012)

Surface Modification of ZrO[2] -3Y[2]O[3] Ceramics with High-Intensity Pulsed N{2+} Ion Beams; Surface Modification of Materials by Ion Beams (SMMIB-2019)
Vydáno: (2019)

Behavior of AL-SI-N nanostructured coatings under the ions (HE{+}, AR{+}, Xe{+}[2] ) irradiation; Energy Fluxes and Radiation Effects (EFRE-2016)
Vydáno: (2016)

High-intensity ion beams with submillisecond duration for synergistic of ion implantation and energy impact on the surface; Energy Fluxes and Radiation Effects (EFRE); International Conference on Modification of Materials with Particle Beams and Plasma Flows (16th CMM)
Vydáno: (2022)

Modification of optical and photoelectrical properties of thin gallium oxide films by intense pulsed 200 keV C+ ion beams; Optical Materials: X; Vol. 25
Vydáno: (2025)

Structural Modification of Graphene on Copper Substrates Irradiated by Nanosecond High-Intensity Ion Beam; Russian Physics Journal; Vol. 61, No. 8
Vydáno: (2018)

Effect of high intensity short-pulsed ion irradiation on optical properties of multilayer coatings of aluminum and silicon nitrides; Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms; Vol. 494-495
Vydáno: (2021)

Effect of irradiation with continuous 28 MeV He2+ ion beam and short-pulsed 200 keV C+ ion beam on optical properties of multilayer Al-Si-N coatings; Radiation Effects and Defects in Solids; Vol. 176, iss. 3-4
Vydáno: (2021)

Deformation of samples of silumin AK5M2 doped with titanium by irradiation of the film/substrate system with a pulsed electron beam; Materials in External Fields ((ISMEF 2022) )
Vydáno: (2022)

Formation of hardened layer in WC-TiC-Co alloy by treatment of high intensity pulse ion beam and compression plasma flows; Surface and Coatings Technology; Vol. 204, iss. 12-13
Vydáno: (2010)