Structures of binary metallic nanoparticles produced by electrical explosion of two wires from immiscible elements; Powder Technology; Vol. 288

Structures of binary metallic nanoparticles produced by electrical explosion of two wires from immiscible elements; Powder Technology; Vol. 288

Bibliographic Details
Parent link:	Powder Technology Vol. 288.— 2016.— [P. 371-378]
Corporate Authors:	Национальный исследовательский Томский политехнический университет Институт физики высоких технологий Кафедра физики высоких технологий в машиностроении Сетевая научно-образовательная лаборатория "Медицинское материаловедение", Национальный исследовательский Томский политехнический университет Институт физики высоких технологий Кафедра физики высоких технологий в машиностроении
Other Authors:	Lerner M. I. Marat Izrailyevich, Pervikov A. V. Alexander Vasilyevich, Glazkova E. A. Elena Alekseevna, Svarovskaya N. V. Natalia Valentinovna, Lozhkomoev A. S. Aleksandr Sergeevich, Psakhie S. G. Sergey Grigorievich
Summary:	Title screen In this study, Cu/Ag, ?u/Pb and Al/Pb binary metallic nanoparticles were synthesized by the electrical explosion of two twisted wires from immiscible elements (i.e., ?u–Ag, Cu–Pb and Al–Pb). The distribution of metallic components in the nanoparticles depended on the melting temperature, metal density, and degree of initial wire superheating. Different types of nanoparticles, such as nanoparticles with no separation between the metal phases, as well as core-shell and Janus nanoparticles were formed depending on the process parameters and the characteristics of the metals. Certain binary metallic nanoparticles were formed when the metal clusters were combined and formed during the initial stages of dispersing the two wires using a pulse of electrical current. Режим доступа: по договору с организацией-держателем ресурса
Language:	English
Published:	2016
Subjects:	электронный ресурс труды учёных ТПУ бинарные металлические системы наночастицы электрические взрывы
Online Access:	http://dx.doi.org/10.1016/j.powtec.2015.11.037
Format:	Electronic Book Chapter
KOHA link:	https://koha.lib.tpu.ru/cgi-bin/koha/opac-detail.pl?biblionumber=649023

Similar Items

Mechanism of the formation of the structure and phase state of binary metallic nanoparticles obtained by the electric explosion of two wires made of different metals; Current Applied Physics; Vol. 17, iss. 11
by: Pervikov A. V. Alexander Vasilyevich
Published: (2017)

Structural characteristics of copper nanoparticles produced by the electric explosion of wires with different structures of metal grains; Current Applied Physics; Vol. 17, iss. 2
by: Pervikov A. V. Alexander Vasilyevich
Published: (2017)

Influence of Conditions of Copper Wires Electric Explosion on Dispersity of Produced Nanopowders; Applied Mechanics and Materials; Vol. 682 : Innovation Technology and Economics in Engineering
Published: (2014)

Particle Size Distribution of Aluminum Powders Obtained by Electric Explosion of Wires; Key Engineering Materials; Vol. 712 : Advanced Materials for Technical and Medical Purpose (AMTMP 2016)
Published: (2016)

Optimal Modes for the Fabrication of Aluminum Nanopowders by the Electrical Explosion of Wires; Advances in Materials Science and Engineering; Vol. 2017
by: Pustovalov A. V. Aleksey Vitalievich
Published: (2017)

Two-dimensional model of laser alloying of binary alloy powder with interval of melting temperature; AIP Conference Proceedings; Vol. 1893 : High-Energy Processes in Condensed Matter (HEPCM 2017)
by: Knyazeva A. G. Anna Georgievna
Published: (2017)

Properties of powders produced by electrical explosions of copper-nickel alloy wires; Materials Letters; Vol. 61, № 14-15
Published: (2007)

Characterization of Naturally Aged Iron Nanopowder Produced by Electrical Explosion of Wires; Metals and Materials International; Vol. XX
by: Nazarenko O. B. Olga Bronislavovna
Published: (2019)

Production of Iron Nanopowders by the Electric Explosion of Wire; Applied Mechanics and Materials; Vol. 1097 : Nanomaterials and Surface Technologies, Materials Applications
by: Pustovalov A. V. Aleksey Vitalievich
Published: (2015)

Synthesis of Al nanoparticles and Al/AlN composite nanoparticles by electrical explosion of aluminum wires in argon and nitrogen; Powder Technology; Vol. 295
Published: (2016)

Electrical explosion of metals in fast-rising megagauss magnetic fields; Physics of Plasmas; Vol. 15, iss. 4
Published: (2009)

Production of tantalum nanopowders by electric explosion of wire; Journal of Physics: Conference Series; Vol. 741 : Optoelectronics, Photonics, Engineering and Nanostructures (Saint Petersburg OPEN 2016)
by: Vlasyuk M. N. Mikhail Nikolaevich
Published: (2016)

Breakup and explosion of droplets of two immiscible fluids and emulsions; International Journal of Thermal Sciences; Vol. 142
by: Antonov D. V. Dmitry Vladimirovich
Published: (2019)

Discharge phenomena associated with a preheated wire explosion in vacuum: Theory and comparison with experiment; Physics of Plasmas; Vol. 15, iss. 1
Published: (2007)

Chemical reactions between metals and active gases in the electric explosion of wires for the production of nanoparticles; Mendeleev Communications; Vol. 11, iss. 7
Published: (2001)

Carbide-nanopowders produced by electrical explosion of wires; Journal of optoelectronics and advanced materials; Vol. 9, № 5
by: Ilyin A. P. Aleksandr Petrovich
Published: (2007)

Исследование радиационно-защитных свойств композиционных материалов на основе бинарных систем несмешивающихся металлов; Физико-технические проблемы в науке, промышленности и медицине
Published: (2022)

Diagnostics of Metal Nanopowders Produced by Electrical Explosion of Wires: Chap.; Progress in Material Science and Engineering; Vol. 351 : Studies in Systems, Decision and Control (SSDC)
by: Nazarenko O. B. Olga Bronislavovna
Published: (2021)

"Water bath" effect during the electrical underwater wire explosionn; Physics of Plasmas; Vol. 14, iss. 10
by: Oreshkin V. I. Vladimir Ivanovich
Published: (2007)

Synthesis of W-Cu composite nanoparticles by the electrical explosion of two wires and their consolidation by spark plasma sintering; Materials Research Express; Vol. 6, iss. 12
Published: (2019)

Child droplets from micro-explosion of emulsion and immiscible two-component droplets; International Journal of Heat and Mass Transfer; Vol. 169
Published: (2021)

Formation of 2D nanoparticles with block structure in simultaneous electric explosion of conductors; AIP Conference Proceedings; Vol. 1623 : International Conference on Physical Mesomechanics of Multilevel Systems 2014, Tomsk, Russia, 3–5 September 2014
Published: (2014)

Spark plasma sintering of alumina nanopowders produced by electrical explosion of wires; SpringerPlus; Vol. 4, iss. 1
by: An V. V. Vladimir Vilorievich
Published: (2015)

Measuring temperature of emulsion and immiscible two-component drops until micro-explosion using two-color LIF; International Journal of Heat and Mass Transfer; Vol. 163
Published: (2020)

Binary phase diagrams based on elements VIIIA and IB periods of the D. I. Mendeleev's table and features of crystallographic parameters; IOP Conference Series: Materials Science and Engineering; Vol. 168 : Radiation-Thermal Effects and Processes in Inorganic Materials (RTEP2016)
Published: (2017)

Modeling the micro-explosion of miscible and immiscible liquid droplets; Acta Astronautica; Vol. 171
Published: (2020)

Structure and Properties of Nanoparticles Formed under Conditions of Wire Electrical Explosion; European Nano Systems 2005 (ENS 2005)
Published: (2005)

Characteristics of nanopowders produced by wire electrical explosion oftinned copper conductor in argon; Materials Lettersэ; Vol. 62, № 17-18
Published: (2008)

The Electric Explosion of Conductors in Megagauss Magnetic Fields; Bulletin of the Russian Academy of Sciences: Physics; Vol. 82, № 4
Published: (2018)

Research of electro-explosive iron powder using the hydrolytic adsorption method; AIP Conference Proceedings; Vol. 1772 : Prospects of Fundamental Sciences Development (PFSD-2016)
by: Ikonnikova K. V. Ksenia Vladimirovna
Published: (2016)

Accounting for Radiation in the Simulation of Electrical Explosion of Conductors; Energy Fluxes and Radiation Effects (EFRE-2020 online)
by: Oreshkin V. I. Vladimir Ivanovich
Published: (2020)

Formation of chemical compounds in the electrical explosion of metal wires in liquids; Russian Physics Journal; Vol. 39, iss. 6
by: Ilyin A. P. Aleksandr Petrovich
Published: (1996)

Foil explosion and decay of metastable state; Physics of Plasmas; Vol. 26, iss. 6
Published: (2019)

Nanopowders produced by electrical explosion ofaluminum wires in water; The second International Forum on Strategic Technology (IFOST-2007), Oct. 3-6, 2007
by: Ilyin A. P. Aleksandr Petrovich
Published: (2007)

Passivation process for superfine aluminum powders obtained by electrical explosion of wires; Applied Surface Science; Vol. 211, iss. 1-4
Published: (2003)

Structural features of ultrafine powders, generated in conditions of wire electrical explosion; Korus 2000; Part 3 : Machine Parts and Materials Processing
Published: (2000)

Assignment of Appropriate Conditions for Synthesizing Tungsten Nanopowder by Electric Explosion of Conductors; IOP Conference Series: Materials Science and Engineering; Vol. 142 : Innovative Technologies in Engineering
Published: (2016)

Numerical simulation of electrical explosions in megagauss magnetic fields; Journal of Physics: Conference Series; Vol. 830 : Energy Fluxes and Radiation Effects 2016
Published: (2017)

The behavior limestone under explosive load; Journal of Physics: Conference Series; Vol. 774 : Equations of State for Matter (ELBRUS 2016)
by: Orlov M. Yu. Maksim Yurjevich
Published: (2016)

Phase state of matter during metal and binary alloy conductor dispersion by a pulse of current; AIP Conference Proceedings; Vol. 1623 : International Conference on Physical Mesomechanics of Multilevel Systems 2014, Tomsk, Russia, 3–5 September 2014
Published: (2014)