
<div class="publication-info">
	<h3>Systematization of physical properties polytherms of metallic melts / Tyagunov A.G., Baryshev E.E., Tyagunov G.V., Mushnikov V.S., Tsepelev V.S. // Izvestiya Vysshikh Uchebnykh Zavedenij. Chernaya Metallurgiya. - 2017. - V. 60, l. 4. - P. 310-317.</h3>
	<dl>
		<dt>ISSN:</dt><dd>03680797</dd>
		<dt>Type:</dt><dd>Article</dd>
				<dt>Abstract:</dt><dd>The analysis of the research results of temperature dependences of the kinematic viscosity, electrical resistivity, surface tension and density of liquid steels and alloys during heating and the subsequent cooling was performed. The identified characteristics formed the basis for systematization of physical properties polytherms of steels and alloys. It was established that the changes occur in the melt structure during heating up to certain critical temperatures. As a result, the cooling polytherms acquire a different view, more close to equilibrium classical patterns and do not coincide with heating polytherms. The branching of the temperature dependences of the physical properties or hysteresis of polytherms is irreversible only when heating up to a temperature not lower than the critical ones. If these conditions are not met the partial or full return to the primary structure of melt can occur and it has an impact on the value of the polytherms hysteresis. Therefore, the hysteresis value, along with the data on the properties, is a qualitative characteristic of the melt structure and its deviations from the equilibrium and micro homogeneous state. The uniformity of distribution of alloying elements atoms into micro groups or clusters indicates the equilibrium of the structure and uniformity of clusters distribution, different in structure in the melt volume, reflects its structural micro-homogeneity. In the process of studying the properties of multicomponent metal materials it was found that after melting the change of melt properties at isothermal holding is a typical pattern of damped oscillations. With the increase of temperature the damping mode approaches the aperiodic one, and the relaxation time decreases. The processes responsible for kinetics of isothermal change in the melt properties occur at the micro level. Non-equilibrium industrial metal typically contains inclusions from the initial materials in the form of undissolved particles of graphite in the cast iron, association and aggregation of carbides, nitrides, etc. Bringing such melt into equilibrium state requires a lot of time, normally much more than for the diffusion transfer of atoms within the disbalanced zones. The more complex is the chemical and structural interactions of solid metal, the greater is the separation between the equilibrium and the obtained melt. In such system the new correlations are formed and broken most intensely. In this case the cooperative processes of interaction of new spatial and temporal structures with inherited from the initial materials take place occur, which is reflected by oscillating dependences of the properties of metal melts. The information about the state of the melt prior to solidification enables a scientific foundation for temperature and time regimes of smelting of steel and alloys. Such melt preparation affects its capacity for supercooling, the crystallization rate and the formation of eutectic reinforcing phases, elements segregation, dendrites structure and zonal structure of castings, and in general – the quality and efficiency of steel production. © 2017, National University of Science and Technology MISIS. All rights reserved.</dd>
		<dt>Author keywords:</dt><dd>Alloy; Density; Electrical resistivity; Hysteresis; Kinematic viscosity; Molten steel; Surface tension; Thermo-time treatment</dd>
		<dt>Index keywords:</dt><dd>нет данных</dd>
		<dt>DOI:</dt><dd>10.17073/0368-0797-2017-4-310-</dd>
		<dt>Смотреть в Scopus:</dt>
			<dd>
								<a href="https://www.scopus.com/inward/record.uri?eid=2-s2.0-85026424243&doi=10.17073%2f0368-0797-2017-4-310-317&partnerID=40&md5=bf44ffb16aceacf3a733ef6cde1bd2b1" target="_blank">https://www.scopus.com/inward/record.uri?eid=2-s2.0-85026424243&amp;doi=10.17073%2f0368-0797-2017-4-310-317&amp;partnerID=40&amp;md5=bf44ffb16aceacf3a733ef6cde1bd2b1</a>
							</dd>

		<dt>Соавторы в МНС:</dt>
		<dd>
				</dd>

				<dt>Другие поля</dt>
		<dd>
			<table class="v-table">
			<thead>
				<tr>
					<td class="w8 gar">Поле</td>
					<td>Значение</td>
				</tr>
			</thead>
			<tbody>
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						<td class="gar">Link</td>
						<td>https://www.scopus.com/inward/record.uri?eid=2-s2.0-85026424243&doi=10.17073%2f0368-0797-2017-4-310-317&partnerID=40&md5=bf44ffb16aceacf3a733ef6cde1bd2b1</td>
					</tr>
										<tr>
						<td class="gar">Affiliations</td>
						<td>Ural Federal University named after the First President of Russia B.N. Yeltsin, Ekaterinburg, Russian Federation</td>
					</tr>
										<tr>
						<td class="gar">Author Keywords</td>
						<td>Alloy; Density; Electrical resistivity; Hysteresis; Kinematic viscosity; Molten steel; Surface tension; Thermo-time treatment</td>
					</tr>
										<tr>
						<td class="gar">References</td>
						<td>Elanskii, G.N., Minchevskii, B.V., Kal’Menev, A.A., (2005) Osnovy Proizvodstva I Obrabotki Metallov [Fundamentals of Production and Processing of Metals], p. 416. , Moscow: izd. MGVMI; Elanskii, G.N., (2011) Stal’ I Periodicheskaya Sistema Elementov D.I. Mendeleeva [Steel and Periodic Table of the Elements of D.I. Mendeleev], p. 196. , Moscow: izd. MGVMI; Tsong, T.T., (1990) Atоm-prове Field Ion Microscope, p. 320. , Cambridge: UK, Cambridge University Press, p; Miller, M., Cerezo, A., Hetherington, M., Smith, G., (1996) Atоm-prове Field Ion Microscope, 52, p. 280. , Monographs on the physics and chemistry of materials. Oxford: Oxford University Press; Miller, M., (2000) Atom-Probe Tomography, p. 350. , New York: Springer, p; Michael, K., (2014) Miller, p. 423. , Richard G. Forbes atom-probe tomography the local electrode atom-probe. New York: Springer, p; Larson, D.J., Prosa, T.J., Ulfig, R.M., Geiser, B.P., Kelly, T.F., (2013) Local Electrode Atom-Probe Tomography a user’s Guide, p. 318. , New York: Springer, p; Kellogg, G.L., Measurement of activation energies for field evaporation of tungsten ions as a function of electric field (1984) Phys. Rev. B., 29 (8), pp. 4304-4312; Wada, M., On the thermally activated field evaporation of Surface atoms (1984) Surf. Sci, 145, pp. 451-465; Menand, A., Blavette, D., Temperature dependence of iridium field evaporation rate (1986) J. Phys., 47 (7), pp. 17-20; Saxey, D.W., Correlated ion analysis and the interpretation of atom probe mass spectra (2011) Ultramicroscope, 111 (6), pp. 473-479; Shaburova, N.A., (2013) Theory and Practice of Using External Actions for Melts Processing. Vestnik Yuurgu. Seriya “Metallurgiya, 13 (1), pp. 85-90; Tsepelev, V.S., Konashkov, V.V., Baum, B.A., Tyagunov, G.V., Baryshev, E.E., (2008) Svoistva Metallicheskikh Rasplavov: Sbornik [The Properties of Metallic Melts: Collection]. Ekaterinburg: Izd. UGTU-UPI, 1, p. 383; Baryshev, E.E., Tyagunov, A.G., Stepanova, N.N., Vliyanie struktury rasplava na svoistva zharoprochnykh nikelevykh splavov v tverdom sostoyanii [Effect of melt structure on the properties of heat resisting nickel alloys in the solid state] (2010) Ekaterinburg: Uro RAN, p. 198; Tyagunov, G.V., Baryshev, E.E., Tsepelev, V.S., (2014) Zhidkii Metall. Po-Roshki [Liquid Metal. Powders]. Ekaterinburg: Izd-Vo Umts UPI, p. 192; Petrushin, N.V., Svetlov, I.L., (2001) Physico-Chemical and Structural Parameters of High-Temperature Nickel Alloys. Metally, (2), pp. 63-73; Elanskii, G.N., Elanskii, D.G., (2006) Stroenie I Svoistva Metallicheskikh Rasplavov [Structure and Properties of Metal Melts]. Moscow: MGVMI, p. 228; Zuev, M.V., Burmasov, S.P., Stepanov, A.I., Gudov, A.G., Mur-Zin, A.V., Zheltukhin, E.G., Improvement in steel smelting by studying melt behavior (2013) Steel in Translation, 43 (2), pp. 106-109; Polishchuk, A.D., Polishchuk, D.A., (2013) Kompleksnoe Otsenivanie V Sistemnykh Issledovaniyakh: Sbornik, pp. 368-370. , T. 1. [Complex estimation in system research: Coll. Vol. 1]. Bulgaria, Varna; Kolotukhin, E.V., Improvement of the technology of smelting and improvement of the quality of high-temperature alloys on the basis of studies of their electrical resistivity. In: Svoistva metallicheskikh rasplavov: Sbornik (2008) The Properties of Metallic Melts: Collection, pp. 113-122. , Part 2]. Ekaterinburg: UGTU-UPI; Peijie, L., Cuangdao, M., Okhapkin, A.V., Konstantinova, N.Y., Sabirzianov, A.A., Popel, P.S., Micro-mechanism for the evolution of viscosity versus temperature in magnesium-aluminum alloy mtlts (2012) Procedia, 27, pp. 871-879; Beltyukov, A.L., Menshikova, S.G., Ladyanov, V.I., The viscosity of binary Al-Fe melts in the Al-rich area (2015) Jornal of Non-Crystalline Solids, 410, pp. 1-6; Tret’Yakova, E.E., (1986) Optimizatsiya Tekhnologii Vyplavki I Uluchshenie Kachestva Khromistykh Stalei Na Osnove Issledovanii Poverkhnost-Nogo Natyazheniya Ikh Rasplavov., p. 23. , Avtoref. diss. … kand. tekhn. nauk [Optimization technology of smelting and improvement of the quality of chromium steels on the basis of studies of the surface tension of their melts. Abstract of Cand. Sci. Diss.]. Sverdlovsk: UPI; Popel’, P.S., Metastable micro-heterogeneity of melts in systems with eutectic and monotectic and its effect on the alloy structure after solidification (2005) Rasplavy, (1), pp. 22-48; Popel, P.S., Chikova, O.A., Matveev, V.M., Metastable collodial stats of liquid metallic solutions (1995) High Temperature Materials and Processes, 14 (4), pp. 219-234; Brodova, I.G., Popel, P.S., Eskin, G.I., (2002) Liquid Metal Processing: Applications to Aluminium Alloy Production, p. 269. , London, New York: Taylor & Francis, p</td>
					</tr>
										<tr>
						<td class="gar">Publisher</td>
						<td>National University of Science and Technology MISIS</td>
					</tr>
										<tr>
						<td class="gar">CODEN</td>
						<td>IVUMA</td>
					</tr>
										<tr>
						<td class="gar">Language of Original Document</td>
						<td>Russian</td>
					</tr>
										<tr>
						<td class="gar">Abbreviated Source Title</td>
						<td>Izv Vyssh Uchebn Zaved Chern Metall</td>
					</tr>
										<tr>
						<td class="gar">Source</td>
						<td>Scopus</td>
					</tr>
								</tbody>
			</table>
		</dd>
			</dl>

</div>
Поле	Значение
Link	https://www.scopus.com/inward/record.uri?eid=2-s2.0-85026424243&doi=10.17073%2f0368-0797-2017-4-310-317&partnerID=40&md5=bf44ffb16aceacf3a733ef6cde1bd2b1
Affiliations	Ural Federal University named after the First President of Russia B.N. Yeltsin, Ekaterinburg, Russian Federation
Author Keywords	Alloy; Density; Electrical resistivity; Hysteresis; Kinematic viscosity; Molten steel; Surface tension; Thermo-time treatment
References	Elanskii, G.N., Minchevskii, B.V., Kal’Menev, A.A., (2005) Osnovy Proizvodstva I Obrabotki Metallov [Fundamentals of Production and Processing of Metals], p. 416. , Moscow: izd. MGVMI; Elanskii, G.N., (2011) Stal’ I Periodicheskaya Sistema Elementov D.I. Mendeleeva [Steel and Periodic Table of the Elements of D.I. Mendeleev], p. 196. , Moscow: izd. MGVMI; Tsong, T.T., (1990) Atоm-prове Field Ion Microscope, p. 320. , Cambridge: UK, Cambridge University Press, p; Miller, M., Cerezo, A., Hetherington, M., Smith, G., (1996) Atоm-prове Field Ion Microscope, 52, p. 280. , Monographs on the physics and chemistry of materials. Oxford: Oxford University Press; Miller, M., (2000) Atom-Probe Tomography, p. 350. , New York: Springer, p; Michael, K., (2014) Miller, p. 423. , Richard G. Forbes atom-probe tomography the local electrode atom-probe. New York: Springer, p; Larson, D.J., Prosa, T.J., Ulfig, R.M., Geiser, B.P., Kelly, T.F., (2013) Local Electrode Atom-Probe Tomography a user’s Guide, p. 318. , New York: Springer, p; Kellogg, G.L., Measurement of activation energies for field evaporation of tungsten ions as a function of electric field (1984) Phys. Rev. B., 29 (8), pp. 4304-4312; Wada, M., On the thermally activated field evaporation of Surface atoms (1984) Surf. Sci, 145, pp. 451-465; Menand, A., Blavette, D., Temperature dependence of iridium field evaporation rate (1986) J. Phys., 47 (7), pp. 17-20; Saxey, D.W., Correlated ion analysis and the interpretation of atom probe mass spectra (2011) Ultramicroscope, 111 (6), pp. 473-479; Shaburova, N.A., (2013) Theory and Practice of Using External Actions for Melts Processing. Vestnik Yuurgu. Seriya “Metallurgiya, 13 (1), pp. 85-90; Tsepelev, V.S., Konashkov, V.V., Baum, B.A., Tyagunov, G.V., Baryshev, E.E., (2008) Svoistva Metallicheskikh Rasplavov: Sbornik [The Properties of Metallic Melts: Collection]. Ekaterinburg: Izd. UGTU-UPI, 1, p. 383; Baryshev, E.E., Tyagunov, A.G., Stepanova, N.N., Vliyanie struktury rasplava na svoistva zharoprochnykh nikelevykh splavov v tverdom sostoyanii [Effect of melt structure on the properties of heat resisting nickel alloys in the solid state] (2010) Ekaterinburg: Uro RAN, p. 198; Tyagunov, G.V., Baryshev, E.E., Tsepelev, V.S., (2014) Zhidkii Metall. Po-Roshki [Liquid Metal. Powders]. Ekaterinburg: Izd-Vo Umts UPI, p. 192; Petrushin, N.V., Svetlov, I.L., (2001) Physico-Chemical and Structural Parameters of High-Temperature Nickel Alloys. Metally, (2), pp. 63-73; Elanskii, G.N., Elanskii, D.G., (2006) Stroenie I Svoistva Metallicheskikh Rasplavov [Structure and Properties of Metal Melts]. Moscow: MGVMI, p. 228; Zuev, M.V., Burmasov, S.P., Stepanov, A.I., Gudov, A.G., Mur-Zin, A.V., Zheltukhin, E.G., Improvement in steel smelting by studying melt behavior (2013) Steel in Translation, 43 (2), pp. 106-109; Polishchuk, A.D., Polishchuk, D.A., (2013) Kompleksnoe Otsenivanie V Sistemnykh Issledovaniyakh: Sbornik, pp. 368-370. , T. 1. [Complex estimation in system research: Coll. Vol. 1]. Bulgaria, Varna; Kolotukhin, E.V., Improvement of the technology of smelting and improvement of the quality of high-temperature alloys on the basis of studies of their electrical resistivity. In: Svoistva metallicheskikh rasplavov: Sbornik (2008) The Properties of Metallic Melts: Collection, pp. 113-122. , Part 2]. Ekaterinburg: UGTU-UPI; Peijie, L., Cuangdao, M., Okhapkin, A.V., Konstantinova, N.Y., Sabirzianov, A.A., Popel, P.S., Micro-mechanism for the evolution of viscosity versus temperature in magnesium-aluminum alloy mtlts (2012) Procedia, 27, pp. 871-879; Beltyukov, A.L., Menshikova, S.G., Ladyanov, V.I., The viscosity of binary Al-Fe melts in the Al-rich area (2015) Jornal of Non-Crystalline Solids, 410, pp. 1-6; Tret’Yakova, E.E., (1986) Optimizatsiya Tekhnologii Vyplavki I Uluchshenie Kachestva Khromistykh Stalei Na Osnove Issledovanii Poverkhnost-Nogo Natyazheniya Ikh Rasplavov., p. 23. , Avtoref. diss. … kand. tekhn. nauk [Optimization technology of smelting and improvement of the quality of chromium steels on the basis of studies of the surface tension of their melts. Abstract of Cand. Sci. Diss.]. Sverdlovsk: UPI; Popel’, P.S., Metastable micro-heterogeneity of melts in systems with eutectic and monotectic and its effect on the alloy structure after solidification (2005) Rasplavy, (1), pp. 22-48; Popel, P.S., Chikova, O.A., Matveev, V.M., Metastable collodial stats of liquid metallic solutions (1995) High Temperature Materials and Processes, 14 (4), pp. 219-234; Brodova, I.G., Popel, P.S., Eskin, G.I., (2002) Liquid Metal Processing: Applications to Aluminium Alloy Production, p. 269. , London, New York: Taylor & Francis, p
Publisher	National University of Science and Technology MISIS
CODEN	IVUMA
Language of Original Document	Russian
Abbreviated Source Title	Izv Vyssh Uchebn Zaved Chern Metall
Source	Scopus