2015-Sustainable Industrial Processing Summit
SIPS 2015 Volume 1: Aifantis Intl. Symp. / Multiscale Material Mechanics
Editors: | Kongoli F, Bordas S, Estrin Y |
Publisher: | Flogen Star OUTREACH |
Publication Year: | 2015 |
Pages: | 300 pages |
ISBN: | 978-1-987820-24-9 |
ISSN: | 2291-1227 (Metals and Materials Processing in a Clean Environment Series) |
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Formation Of The Internal Cavity In Copper Icosahedral Small Particles During Annealing
Anatoly
Vikarchuk1; Anastasiya
Priezzheva1; Maksim
Dorogov1; Leonid
Dorogin2; Alexey
Romanov1; Ilmar
Kink3;
1TOGLIATTI STATE UNIVERSITY, Togliatti, Russian Federation; 2INSTITUTE OF PHYSICS, UNIVERSITY OF TARTU, Tartu, Estonia; 3UNIVERSITY OF TARTU, Tartu, Estonia;
Type of Paper: Keynote
Id Paper: 128
Topic: 1Abstract:
The paper discusses experimentally detected phenomenon of internal cavity formation in icosahedral small copper particles as a result of their annealing. Icosahedral small particle has six five-fold symmetry axes and disclination-type defects inside. Particle consists of 20 tetrahedral region with local fcc atomic arrangement joined via twin boundaries.<br />Our experiments showed that the annealed icosahedral particles have large internal cavities (up to 80 volume %) surrounded by a shell made of metal oxide. The found cavities were examined in scanning electron microscope equipped with focused-ion beam gun. To investigate the structural and phase transformations occurring in the process of icosahedral particle annealing, differential scanning calorimetry (DSC) was applied.<br />It has been shown that the formation of cavities in microparticles was promoted by (i) the presence of oxygen in the surrounding atmosphere and (ii) high internal stresses in the particle interior. The role of disclination-type defects as the sources of internal stresses in the mechanism of internal cavity formation is elucidated.<br />This work has been supported by the grant No 14.B25.31.0011 of the Ministry of Education and Science of Russian Federation (resolution # 220) at Togliatti State University.
Keywords:
Metals; Nanomaterials; Symmetry;
References:
[1] A.A. Vikarchuk, A.P. Volenko Pentagonal copper crystals: various growth shapes and specific features of their internal structure, Physics of the Solid State, 47 (2005), 339-344.
[2] I.S. Yasnikov, A.A. Vikarchuk Effect of heat exchange on the habit of electrodeposited pentagonal microcrystals, Technical Physics Letters, 32 (2006), 825-826.
[3] A.A. Vikarchuk, A.P. Volenko, S.A. Yurchenkova, Disclination-type structural defects of electrodeposited FCC metals, Soviet electrochemistry, 27 (1991), 535-541.
[4] V.G. Gryaznov, A.M. Kaprelov, A.E. Romanov, Pentagonal symmetry and disclinations in small particles. Disclinations and rotational deformations in solid bodies [in Russian], 1988, Academy of sciences of USSR.
[5] L.D. Marks, D.J. Smith, HREM and STEM of defects in multiply-twinned particles, J. Microsc. (Gr. Brit.), 130 (1983), 249-261.
[6] A.A. Vikarchuk, A.P. Volenko, S.A. Bondarenko, Yu.D. Gamburg, Disclination nature of pentagonal crystals that form during copper electrocrystallization, Russian Journal of Electrochemistry, 40 (2004), 180-187.
[7] I.S. Yasnikov, A.A. Vikarchuk, Mechanisms of relaxation of elastic stresses in the process of growth of nanoparticles and microcrystals with disclination defects in electrocrystallization of FCC metals, Metal Science and Heat Treatment, 49 (2007), 97-104.
[8] M. Gillet, Structure of small metallic particles, Surface Science, 67 (1977), 139-157.
[9] S. Giorgio, J. Urban, Fivefold and threefold symmetries in silver clusters, Applied Physics Letters, 52 (1988), 1467-1468.
[10] A.A. Vikarchuk, I.S. Yasnikov, Yu.D. Gamburg, Temperature evolution for small particles formed during electrocrystallization, Russian Journal of Electrochemistry, 44 (2008), 857-860.
[11] A.A. Vikarchuk, M.V. Dorogov, Features of the evolution of the structure and morphology of the surface of icosahedral copper particles in the annealing process, JETP Letters, 97 (2013), 682-686.
[12] A.A. Vikarchuk, N.N. Gryzunova, D.A. Denisova, O.A. Dovzhenko, M.N. Tyurkov, I.I. Tsybuskina, I.S. Yasnikov, New metallic functional materials consisting of pentagonal particles, crystals and tubes. P.I. Mechanisms of formation and structural features of pentagonal particles and crystals [in Russian], Journal of functional materials, 2 (2008), 163-172.
[13] I.S. Yasnikov, A.A. Vikarchuk, Thermodynamics of cavity formation in pentagonal crystals during electrodeposition of copper, Bulletin of the Russian Academy of Sciences: Physics, 69 (2005), 1548-1553.
[14] I.S. Yasnikov, A.A Vikarchuk., D.A. Denisova, N.N. Gryzunova, I.I. Tsybuskina, Electrodeposition of nanostructure objects with pentagonal symmetry, Technical Physics. The Russian Journal of Applied Physics, 52 (2007), 1328-1331.
[15] Y.-W. Park, N.-J. Seong, H.-J. Jung, A. Chanda, S.-G. Yoona, Growth Mechanism of the Copper Oxide Nanowires from Copper Thin Films Deposited on CuO-Buffered Silicon Substrate, Journal of The Electrochemical Society, 157 (2010), K119-K124.
[16] A.I. Mikhailin, A.E. Romanov, Amorphization of a disclination core, Sov. Phys. Solid State, 28 (1986), 337-338.
[17] A.E. Romanov, A. Polonsky, V.G. Gryaznov, S.A. Nepijko, T. Junghanns, N.I. Vitrykhovski, Voids and channels in pentagonal crystals, Journal of Crystal Growth, 129 (1993), 691-698.
[18] C.J. Love, J.D. Smith, Y. Cui, K.K. Varanasi, Size-dependent thermal oxidation of copper: single-step synthesis of hierarchical nanostructures, Nanoscale, 3 (2011), 4972-4976.
[19] M.V. Dorogov, A.N. Priezzheva, S. Vlassov, I. Kink, E. Shulga, L.M. Dorogin, R. Lõhmus, M.N. Tyurkov, A.A. Vikarchuk, A.E. Romanov, Phase and structural transformations in annealed copper coatings in relation to oxide whisker growth, Applied Surface Science, 346 (2015), 423-427.
[20] A.N. Abramova, M.V. Dorogov, S. Vlassov, I. Kink, L.M. Dorogin, R. Lõhmus, A.Е. Romanov, A.A. Vikarchuk, Nanowhisker of copper oxide: fabrication technique, structural features and mechanical properties, Materials Physics and Mechanics, 19 (2014), 88-95.Full Text:
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Vikarchuk A, Priezzheva A, Dorogov M, Dorogin L, Romanov A, Kink I. Formation Of The Internal Cavity In Copper Icosahedral Small Particles During Annealing. In: Kongoli F, Bordas S, Estrin Y, editors. Sustainable Industrial Processing Summit SIPS 2015 Volume 1: Aifantis Intl. Symp. / Multiscale Material Mechanics. Volume 1. Montreal(Canada): FLOGEN Star Outreach. 2015. p. 75-82.