Abonnement à la biblothèque: Guest
Portail numérique Bibliothèque numérique eBooks Revues Références et comptes rendus Collections
High Temperature Material Processes: An International Quarterly of High-Technology Plasma Processes
SJR: 0.137 SNIP: 0.341 CiteScore™: 0.43

ISSN Imprimer: 1093-3611
ISSN En ligne: 1940-4360

High Temperature Material Processes: An International Quarterly of High-Technology Plasma Processes

DOI: 10.1615/HighTempMatProc.2019031163
pages 275-282

CHARACTERISTIC FEATURES OF THE SURFACE RELIEF FORMATION OF METALS MODIFIED BY COMPRESSION PLASMA FLOWS

Raman S. Kudaktsin
A.V. Luikov Heat and Mass Transfer Institute, National Academy of Sciences of Belarus, 15 P. Brovka Str., Minsk, 220072, Belarus
Valiantsin M. Astashynski
A.V. Luikov Heat and Mass Transfer Institute, National Academy of Sciences of Belarus, 15 P. Brovka Str., Minsk, 220072, Belarus; National Research Nuclear University "MEPhI" (Moscow Engineering Physics Institute), 31 Kashirskoe Highway, Moscow, 115409, Russia
A. M. Kuzmitski
A. V. Luikov Heat and Mass Transfer Institute, National Academy of Sciences of Belarus, 15, P. Brovki Str, Minsk 220072, Belarus

RÉSUMÉ

Action of compression plasma flows (CPF) is a promising high-energy method for material modification ensuring uniform distribution of components in ultradeep (to about 100 μm) modified layers. In the present paper, using the scanning electron microscopy, we studied the surface relief and the thickness of a modified layer of W108 steel treated with compression plasma flows. To generate a plasma flux under experimental conditions, a magnetoplasma compressor of compact geometry with an energy storage battery of 15 kJ was used. It was established that during CPF action, the molten layer of material under the action of high-density plasma spreads over the surface. After the end of exposure, at the stage of rapid crystallization of the melt, a developed surface relief is formed with a height difference from 1 to 80 μm. With increase in the energy parameters of the acting CPF, the surface irregularities first increase and then decrease again, which is associated with the melt entrainment in the liquid phase. The dependence of the average melting depth of steel on the power density of the CPF action has been established. It is shown that the heat transfer model based on the Stefan problem allows one to predict the average melting depth of the target with sufficient accuracy; however, to determine the actual thickness of the modified layer, hydrodynamic entrainment and surface irregularities should be taken into account.

RÉFÉRENCES

  1. Aktaev, N.E. and Remnev, G.E., Modeling of Carbon Penetration into Silicon Structure under the Action of Pulsed High-Intensity Ion Beam, Surf. Coat. Technol., vol. 306, part A, pp. 54-57, 2016.

  2. Amati, M., Gregoratti, L., Sezen, H., Grce, A., Milosavljevic, M., and Homewood, K.P., Compositional and Structural Studies of Ion-Beam Modified AlN/TiN Multilayers, Appl. Surf. Sci., vol. 411, pp. 431-436, 2017.

  3. Aono, Y., Hirata, A., and Tokura, H., Non-Textured Laser Modification of Silica Glass Surface: Wettability Control and Flow Channel Formation, Appl. Surf. Sci., vol. 371, pp. 530-537, 2016.

  4. Astashynski, V.M., Ananin, S.I., Emelyanenko, A.S., Kostyukevich, E.A., Kuzmitzky, A.M., Zhvavy, S.P., and Uglov, V.V., Bulk Periodic Structures Formation on Monocrystalline Silicon Surface under the Action of Compression Plasma Flows, Appl. Surf. Sci., vol. 253, no. 4, pp. 1866-1872, 2006.

  5. Astashynski, V.M. and Min'ko, L.Y., Physical Processes in Quasistationary Plasma Accelerators with Ion Current Transfer, in The Physics of Ionized Gases, N. Konjevic, M. Cuk, and S. Durovic, Eds., Belgrade, Serbia: Institute of Physics, pp. 285-303, 1999.

  6. Chernov, V.V., Ivanov, O.A., Isaev, V.A., Radishev, D.B., Vikharev, A.L., and Kozlov, A.V., High-Current Electron Emission of Thin Diamond Films Deposited on Molybdenum Cathodes, Diamond Related Mater., vol. 37, pp. 87-91, 2013.

  7. Earl, C., Castrejon-Pita, J.R., Hilton, P.A., and O'Neill, W., The Dynamics of Laser Surface Modification, J. Manuf Process., vol. 21, pp. 214-223, 2016.

  8. Gahanty, S., Surface Modification of Al-Si Alloy by Excimer Laser Pulse Processing, Mater. Chem. Phys., vol. 173, pp. 192-199, 2016.

  9. Gao, Y., Influence of Pulsed Electron Beams Treatment on Microstructure and Properties of TA15 Titanium Alloy, Appl. Surf. Sci., vol. 264, pp. 633-655, 2013.

  10. Hao, S., Wang, H., and Zhao, L., Surface Modification of 40CrNiMo7 Steel with High Current Pulsed Electron Beam Treatment, Nucl. Instrum. Meth. Phys. Res. Section B: Beam Interactions with Materials and Atoms, vol. 368, pp. 81-85, 2016.

  11. Huang, J., Wang, L., Sun, H., Wang, H., Gao, M., Cheng, W., and Chen, Z., Effects of RTA Temperatures on Conductivity and Micro-Structures of Boron-Doped Silicon Nanocrystals in Si-Rich Oxide Thin Films, Mater. Sci. Semicond. Process., vol. 47, pp. 7-11, 2016.

  12. Jeong, J.W., Huh, J.W., Lee, J.I., and Chu, H.Y., Effects of Thermal Annealing on the Efficiency of Bulk-Heterojunction Organic Photovoltaic Devices, Current Appl. Phys., vol. 10, no. 3, pp. S520-S524, 2010.

  13. Mikoushkin, V.M., Bryzgalov, V.V., Makarevskaya, E.A., Solonitsyna, A.P., and Marchenko, D.E., Modi-fication of the GaAs Native Oxide Surface Layer into the Layer of the Ga2O3 Dielectric by an Ar+ Ion Beam, Surf. Coat. Technol., vol. 344, pp. 149-153, 2018.

  14. Proskurovsky, D.I., Rotshtein, V.P., Ozur, G.E., Ivanov, Yu.F., and Markov, A.B., Physical Foundations for Surface Treatment of Materials with Low Energy, High Current Electron Beams, Surf. Coat. Technol., vol. 125, nos. 1-3, pp. 49-56, 2000.

  15. Smithels, C.J., Smithels Metals Reference Book, 8th Ed., Woburn, MA: Butterworth-Heinemann, 2004.

  16. Utlu, G. and Artunc, N., The Effects of Grain Boundary Scattering on Electrical Resistivity of Ag/NiSi Silicide Films Formed on Silicon Substrate at 500oC by RTA, Appl. Surface Sci., vol. 310, pp. 248-256, 2013.

  17. Zagulyaev, D., Konovalov, S., Gromov, V., Glezer, A., Ivanov, Y., and Sundeev, R., Structure and Properties Changes of Al-Si Alloy Treated by Pulsed Electron Beam, Mater. Lett., vol. 229, pp. 377-380, 2018.

  18. Zhang, Q.X., Ge, Y.P., Gu, X.Q., Peng, F., and Luo, M., The Effects of Rapid Thermal Annealing and Microwave Annealing on the Electrical Properties of ZrO2 Metal-Insulator-Metal Capacitors, Optik, vol. 179, pp. 1057-1062, 2019.


Articles with similar content:

HIGH-TEMPERATURE IN SITU DSC STUDIES OF MULTILAYER ZrN/CrN COATINGS OBTAINED BY CA-PVD
High Temperature Material Processes: An International Quarterly of High-Technology Plasma Processes, Vol.23, 2019, issue 3
S. V. Plotnikov, Olga V. Maksakova, Alexander D. Pogrebnjak, V. M. Beresnev, S. Simoẽs
STRUCTURE OF SURFACE LAYERS OF IRON AND CARBON STEELS TREATED BY COMPRESSION PLASMA FLOWS
High Temperature Material Processes: An International Quarterly of High-Technology Plasma Processes, Vol.8, 2004, issue 2
V. M. Anishchik, V. V. Astashynski, Vladimir V. Uglov, Iryna N. Rumiantseva
THE EFFECT OF SIZE STABILIZATION OF CARBON STEELS AUSTENITE
High Temperature Material Processes: An International Quarterly of High-Technology Plasma Processes, Vol.18, 2014, issue 4
Yurii F. Ivanov, E. V. Kozlov
SUPER HIGH RATE DEPOSITION OF HOMO- AND HETERO-EPITAXIAL SILICON THICK FILMS BY MESO-PLASMA CVD
High Temperature Material Processes: An International Quarterly of High-Technology Plasma Processes, Vol.11, 2007, issue 1
M. Kambara
COMPRESSION PLASMA FLOW INTERRACTION WITH TITANIUM-ON-STEEL SYSTEM: STRUCTURE AND MECHANICAL PROPERTIES
High Temperature Material Processes: An International Quarterly of High-Technology Plasma Processes, Vol.8, 2004, issue 4
V. M. Anishchik, Nikolai N. Cherenda, A. K. Stalmashonak, A. V. Punko, V. M. Astashinski, A. M. Kuzmitski, Vladimir V. Uglov