Characteristics of Temperature Field Distribution during Vacuum-Free Electric Arc Synthesis; Bulletin of the Russian Academy of Sciences: Physics; Vol. 89, Suppl. 2

Characteristics of Temperature Field Distribution during Vacuum-Free Electric Arc Synthesis; Bulletin of the Russian Academy of Sciences: Physics; Vol. 89, Suppl. 2

Bibliografske podrobnosti
Parent link:	Bulletin of the Russian Academy of Sciences: Physics=Известия Российской академии наук. Серия физическая.— .— New York: Allerton Press, Inc. Vol. 89, Suppl. 2.— 2026.— P. S318–S324
Drugi avtorji:	Vasiljeva (Vassilyeva) Yu. Z. Yuliya Zakharovna, Povalyaev P. V. Pavel Vadimovich, Neklya Yu. A. Yuliya Aleksandrovna, Shlyakhov T. S. Timofey Sergeevich, Gerasimov R. D. Roman Dmitrievich, Vlasov A, V. Aleksey Vladimirovich, Pak A. Ya. Aleksandr Yakovlevich
Izvleček:	Title screen We presented experimental studies on the synthesis of tungsten carbide powder by the vacuum-free electric arc method. The optimal parameters of plasma processing of the tungsten–carbon system were determined based on the results of temperature field distribution during vacuum-free electric arc synthesis. Temperature conditions are ensured in the reaction zone at certain parameters—the power supply current is 250–300 A, ensuring a temperature mode of 1700°C. The study of the mass balance showed that the greatest mass losses are observed with an increase in current to 300–350 A. X-ray phase analysis of the synthesized material revealed the predominance of the crystalline phase of tungsten carbide WC Текстовый файл AM_Agreement
Jezik:	angleščina
Izdano:	2026
Teme:	tungsten carbide electric arc discharge synthesis powder temperature field open-air environment электронный ресурс труды учёных ТПУ
Online dostop:	https://doi.org/10.1134/S1062873825714576
Format:	Elektronski Book Chapter
KOHA link:	https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=684562

Podobne knjige/članki

Влияние энергетики процесса безвакуумного электродугового синтеза на продукт переработки вольфрамового рудного концентрата; Известия Томского политехнического университета [Известия ТПУ]. Инжиниринг георесурсов; Т. 335, № 1
Izdano: (2024)

Vacuum-free arc synthesis and characterization of crystalline molybdenum borides as instrumental material; Thermal Science and Engineering Progress; Vol. 67
Izdano: (2025)

Vacuumless synthesis of tungsten carbide in a self-shielding atmospheric plasma of DC arc discharge; International Journal of Refractory Metals and Hard Materials; Vol. 93
Izdano: (2020)

Влияние длительности горения разряда на фазовый состав порошкового карбида бора, полученного в атмосферной плазме дугового разряда постоянного тока; Инновационные технологии в машиностроении
od: Мартынов Р. С.
Izdano: (2019)

Cubic SiC nanowire synthesis by DC arc discharge under ambient air conditions; Surface and Coatings Technology; Vol. 387
Izdano: (2020)

Synthesis of Crystalline Tungsten Carbide Phases under the Influence of Atmospheric Electrical Arc Plasma on Tungsten Oxide; Journal of Superhard Materials; Vol. 43, iss. 3
Izdano: (2021)

Электродуговой синтез карбида вольфрама из рудных концентратов; Известия Томского политехнического университета [Известия ТПУ]. Инжиниринг георесурсов; Т. 332, № 5
od: Пак А. Я. Александр Яковлевич
Izdano: (2021)

Hard Metal Waste Recycling by the Atmospheric Direct Current Arc Plasma; Energy Fluxes and Radiation Effects (EFRE-2020 online)
od: Kokorina A. I. Aleksandra Ivanovna
Izdano: (2020)

Влияние энергии на фазовый состав продукта электродугового синтеза системы "вольфрам-углерод" , полученный в самоэкранирующейся автономной газовой среде; Перспективные материалы; № 10
od: Пак А. Я. Александр Яковлевич
Izdano: (2020)

Obtaining a Material Based on Я-SiC and Carbon Fibers Using an Electric Arc Technique; Inorganic Materials: Applied Research; Vol. 10, iss. 4
Izdano: (2019)

Synthesis of transition metal carbides and high-entropy carbide TiZrNbHfTaC5 in self-shielding DC arc discharge plasma; Ceramics International; Vol. 48, iss. 2
Izdano: (2022)

Spatial stabilization of arc discharges in pulsed gas tungsten arc welding; Welding in the World; Vol. 68, iss. 9
Izdano: (2024)

Synthesis of molybdenum carbide catalyst by DC arc plasma in ambient air for hydrogen evolution; Materials Chemistry and Physics; Vol. 254
Izdano: (2020)

Composite material WC1-x@C as a noble-metal-economic material for hydrogen evolution reaction; Journal of Alloys and Compounds; Vol. 834
Izdano: (2020)

Synthesis of silicon carbide using an AC atmospheric-pressure arc reactor; Journal of Alloys and Compounds; Vol. 1003
Izdano: (2024)

Formation of filamentary crystals in intermediate combustion product of aluminium nanopowder and its mixtures with molybdenum and tungsten nanopowders in air; Bulletin of the Tomsk Polytechnic University; Vol. 310, № 2
od: Tolbanova L. O. Lyudmila Olegovna
Izdano: (2007)

Synthesis of ultrafine cubic tungsten carbide in a discharge plasma jet; International Journal of Refractory Metals and Hard Materials; Vol. 48
Izdano: (2015)

Energy-efficient direct current arc plasma synthesis of tantalum carbide powder by advanced vacuum-free method; International Journal of Refractory Metals and Hard Materials; Vol. 112
Izdano: (2023)

In-situ carbide reinforced aluminium metal matrix composites obtained in pulsed arc plasma discharge; Ceramics International; Vol. 51, iss. 14
Izdano: (2025)

Structure of composite powders "TiC - high chromium cast iron binder" produced by SHS method; Mechanical Engineering, Automation and Control Systems (MEACS)
od: Kalambaeva S. S.
Izdano: (2014)

Influence of Nanostructured Powder Modifiers on the Structure of a Welding Bead; Advanced Materials Research; Vol. 872
Izdano: (2014)

Obtaining Superhard Coatings of Cubic Tungsten Carbide under High-speed Plasma Spraying; Energy Fluxes and Radiation Effects (EFRE-2020 online)
Izdano: (2020)

Synthesis of Mo2C-based material in DC arc discharge plasma under ambient air conditions; Materials Chemistry and Physics; Vol. 314
Izdano: (2024)

Synthesis of hafnium carbide powder in atmospheric arc plasma; Technical Physics; Vol. 68, No. 6
Izdano: (2023)

Influence of energy on the phase composition of the ultra-dispersed product of the molybdenum–carbon system obtained by the vacuumless arc discharge method; High Temperature Material Processes: An International Quarterly of High-Technology Plasma Processes; Vol. 24, iss. 1
od: Pak A. Ya. Aleksandr Yakovlevich
Izdano: (2020)

Plasma dynamic synthesis of hybrid carbide-reinforced aluminium matrix composites; Particuology; Vol. 109
Izdano: (2026)

Получение порошков меди и металломатричных композитов с медной матрицей в плазме дугового разряда; Известия Томского политехнического университета [Известия ТПУ]. Инжиниринг георесурсов; Т. 337, № 2
Izdano: (2026)

Искровое плазменное спекание объемных материалов на основе SiC из углеродистого остатка термической переработки рисовой шелухи; Известия Томского политехнического университета [Известия ТПУ]. Инжиниринг георесурсов; Т. 335, № 4
Izdano: (2024)

Initiation of an Arc Discharge in a Coaxial Magnetoplasma Accelerator; Russian Electrical Engineering; Vol. 89, iss. 3
od: Sivkov A. A. Aleksandr Anatolyevich
Izdano: (2018)

Advanced Arc Plasma Synthesis of Biomorphic Silicon Carbide Using Charcoal and Silicon Dioxide in Air; Waste and Biomass Valorization; Vol. 13, iss. 1
Izdano: (2021)

Effect of Nitrogen Arc Discharge Plasma Treatment on Physicochemical Properties and Biocompatibility of PLA-Based Scaffolds; Polymers; Vol. 15, iss. 16
Izdano: (2023)

Numerical Simulation of Thermal Processes and the Effect of Heating of Near-Surface Layers of Titanium on the Diffusion Transfer of Dopants during High-Intensity Pulsed Ion Implantation; Journal of Surface Investigation. X-ray, Synchrotron and Neutron Techniques; Vol. 17, iss. 6
od: Ivanova A. I. Anna Ivanovna
Izdano: (2023)

The Possibility of Synthesizing Nanosize Molybdenum Carbide in Atmospheric Electrodischarge Plasma; Technical Physics Letters; Vol. 45, iss. 9
od: Pak A. Ya. Aleksandr Yakovlevich
Izdano: (2019)

Production of HfTaTiNbZrC5 High-Entropy Carbide Micropowder in the Plasma of an Atmospheric Pressure Arc Discharge; Journal of Engineering Physics and Thermophysics; Vol. 94, iss. 1
Izdano: (2021)

Каталитические свойства порошков карбида вольфрама в процессе крекинга тяжелого углеводородного сырья; Известия Томского политехнического университета [Известия ТПУ]. Инжиниринг георесурсов; Т. 328, № 8
Izdano: (2017)

Concentration of CO2 in the Local Working Area during the Joint Operation of a Gas Infrared Heater and an Air-Exchange System; Energies; Vol. 17, iss. 1
Izdano: (2023)

Comparison of glow, arc, and magnetron direct current discharges; Resource-Efficient Technologies; No 2
od: Abrahamyan A. S.
Izdano: (2019)

Плазмодинамический синтез кубического карбида вольфрама с изменяемой стехиометрией; Неорганические материалы; Т. 57, № 4
Izdano: (2021)

Heterogeneous Arc Discharge Plasma in a Magnetic Field; Russian Physics Journal; Vol. 60, iss. 7
Izdano: (2017)

Dependence of the Product's Phase Composition on the Ratio of Precursors in Plasmadynamic Synthesis of Silicon Carbide; Key Engineering Materials; Vol. 769 : High Technology: Research and Applications (HTRA 2017)
od: Sivkov A. A. Aleksandr Anatolyevich
Izdano: (2018)