Напряжения в локальных объемах при реактивном спекании порошковой смеси Ti-Al-Fe-Fe₂O₃

Авторы

M.A. Anisimova ¹ , А.Г. Князева ¹

¹ Институт физики прочности и материаловедения СО РАН, Академический пр., 2/4, Томск, 634055, Россия

10.17586/2687-0568-2024-6-3-132-156

Rev. Adv. Mater. Technol., 2024, vol. 6, no. 3, pp. 132–156

Аннотация

Композиты на основе титана и алюминия привлекают внимание уже несколько десятилетий. Один из возможных способов создания таких композитов основан на реакционно (реактивном) спекании, которое подразумевает спекание с сопутствующими химическими реакциями, следствием которых является изменение фазового состава. В число реакций могут непосредственно входить те, которые приводят к образованию упрочняющей фазы. Весьма перспективными для использования в этом направлении являются смеси типа Ti-Al-Fe-Fe2O3, где источником оксида железа являются отходы металлообработки. Однако для многокомпонентных систем закономерности фазообразования, как и возникновения напряжений в диффузионной зоне, не очевидны и не одинаковы для всего объема реакционных смесей. В настоящей работе описываются общие идеи и методы моделирования реакционного спекания, а также дается обзор ситуаций, наиболее важных для фазообразования в выбранной смеси. Показано, что динамика роста фаз и напряжений может быть различной в разных локальных объемах с различными вариантами взаимодействия частиц друг с другом.

Ключевые слова

реактивная диффузия; рост фаз; напряжения

Финансирование

Russian Science Foundation and the Tomsk Region Administration: 22-13-20031

Ссылки

1.    E.N. Korosteleva, A.G. Knyazeva, I.O. Nikolaev, Phase Formation in Reactive Sintering with Reduction, Phys. Mesomech., 2023, vol. 26, pp. 39-47.
2.    M. Anisimova, A. Knyazeva, Basic models of phase formation at the mesolevel under reactive sintering of Ti-Al-Fe2O3 powder mixture, in: D. Sorokin, A. Grishkov (Eds.), Proceeding of 8th International Congress on Energy Fluxes and Radiation Effects (EFRE 2022), Institute of High Current Electronics SB RAS, HCEI SB RAS, 2022.
3.    E.L. Shvedkov, E.T. Denisenko, Kovensky I.I., Slovar-spravochnik po poroshkovoy metallurgii [Dictionary-handbook of powder metallurgy], Naukova dumka Publ., Kyiv, 1982 (in Russian).
4.    M. Kizilyalli, J. Corish, R. Metselaar, Definitions of terms for diffusion in the solid state, Pure Appl. Chem., 1999, vol. 71, no. 7, pp. 1307-1325.
5.    V.N. Chebotin, Chemical diffusion in solids, Nauka, Moscow, 1989 (in Russian).
6.    V.I. Dybkov, Solid state reaction kinetics, IPMS Publications, Kyev, 2013.
7.    A.M. Gusak, T.V. Zaporozhets, Y.O. Lyashenko, S.V. Kornienko, M.O. Pasichnyy, A.S. Shirinyan, Diffusion-Controlled Solid State Reactions: In Alloys, Thin-Films, and Nanosystems, John Wiley and Sons, New York, 2010.
8.    J. Svoboda, F.D Fischer, A new computational treatment of reactive diffusion in binary systems, Comput. Mater. Sci., 2013, vol. 78, pp. 39-46.
9.    Y.M. Grigor'ev, S.L. Kharatyan, Z.S.Andrianova, A.N. Ivanova, A.G. Merzhanov, Diffusion kinetics of interaction of metals with gases, Combust. Explos. Shock Waves, 1977, vol. 13, pp. 604-610.
10.    Y.M. Grigor'ev, S.L. Kharatyan, Z.S. Andrianova, A.N. Ivanova, A.G. Merzhanov, Theory of reaction diffusion for bodies of plane, cylindrical, and spherical symmetry, J. Eng. Phys., 1977, vol. 33, pp. 1353-1358.
11.    J. Benar, Oxidation of Metals, Metallurgiya, Moscow, 1968 (in Russian).
12.    J. Svoboda, F.D. Fischer, P. Fratzl, Diffusion and creep in multi-component alloys with non-ideal sources and sinks for vacancies, Acta Mater., 2006, vol. 54, no. 11, pp. 3043-3053.
13.    K.P. Gurov, E.A. Smirnov, A.N. Shabalin, Diffuziya i kinetika fazovykh prevrashcheniy v metallakh i splavakh [Diffusion and kinetics of phase transformations in metals and alloys], MEPHI, Moscow, 1990 (in Russian).
14.    B.Ya. Lyubov, Kinetic Theory of Phase Transformations, Amerind Pub., New Delhi, 1978.
15.    G.D.C. Kuiken, Thermodynamics of irreversible processes. Applicationa to diffusion and rheology, J. Wiley and Sons, Chichester, 1994.
16.    I. Kaur, W. Gust. Fundamentals of Grain and Interphase Boundary Diffusion, Ziegler Press, Stuttgart, 1989.
17.    Y.L. Corcoran, A.H. King, N. de Lanerolle, B. Kim, Grain Boundary Diffusion Layers on Silicon and Growth of Titanium Silicide, J. Electron. Mater., 1990, vol.19, pp. 1177-1183.
18.    H.H. Farrell, G.H. Glimer, M. Suenaga, Grain boundary diffusion and growth of intermetallic layers, J. Appl. Phys., 1974, vol. 45, no. 9, pp. 4025-4035.
19.    A. Furuto, M. Kajihara, Numerical Analysis for Kinetics of Reactive Diffusion Controlled by Boundary and Volume Diffusion in a Hypothetical Binary System, Mater. Trans., 2008, vol. 49, no. 2, pp. 294-303.
20.    D.L. Bekea, Yu. Kaganovskii, G.L. Katona, Interdiffusion along grain boundaries - Diffusion induced grain boundary migration, low temperature homogenization and reactions in nanostructured thin films, Prog. Mater. Sci., 2018, vol. 98, pp. 625-674.
21.    A.M. Gusak, Flux-Driven Lateral Grain Growth during Reactive Diffusion, Metallofiz. Noveishie Tekhnol., 2020, vol. 42, no. 10, pp. 1335-1346.
22.    M.V. Chepak-Gizbrekht, A.G. Knyazeva, Two-dimensional model of grain boundary diffusion and oxidation, PNRPU Mechanics Bulletin, 2022, no. 1, pp. 156-166.
23.    M.V. Chepak-Gizbrekht, A.G. Knyazeva, Oxidation of TiAl alloy by oxygen grain boundary diffusion, Intermetallics, 2023, vol. 162, art. no. 107993.
24.    M.V. Chepak-Gizbrekht, A.G. Knyazeva, Modeling the oxidation process of TiAl and Ti3Al intermetallic compounds due to grain-boundary diffusion of oxygen, Uchenye Zapiski Kazanskogo Universiteta. Seriya Fiziko-Matematicheskie Nauki, 2023, vol. 165, no 3, pp. 307-321 (in Russian).
25.    A. Knyazeva, O. Kryukova, A. Maslov, Two-level model of the grain boundary diffusion under electron beam action, Comput. Mater. Sci., 2021, vol. 196, art. no. 110548.
26.    G. Wang, B. Gleeson, D.L. Douglass, Phenomenological Treatment of Multilayer Growth, Oxid Met., 1989, vol. 31, no. 5-6, pp. 415-429.
27.    B. Cockeram, G. Wang, The influence of multi-layered kinetics on the selection of the primary phase during the diffusion-controlled growth of titanium-silicide layers, Thin Solid Films, 1995, vol. 269, no. 1-2, pp. 57-63.
28.    G.-X. Li, C.W. Powell, Theory of reaction diffusion in binary systems, Acta Metall., 1985, vol. 33, no. 1, pp. 23-31.
29.    V.I. Dybkov, Reaction diffusion in binary solid-solid, solid-liquid and solid-gaz sestems: common and distinctive features, Defect Diffus Forum, 2001, vol. 194-199, pp. 1503-1533.
30.    U. Gösele; K.N. Tu, "Critical thickness" of amorphous phase formation in binary diffusion couples, J. Appl. Phys., 1989, vol. 66, no. 6, pp. 2619-2626.
31.    M. Kajihara, Influence of Temperature Dependence of Solubility on Kinetics for Reactive Diffusion in a Hypothetical Binary System, Mater. Trans., 2008, vol. 49, no. 4, pp. 715-722.
32.    M. Kajihara, Analysis of kinetics of reactive diffusion in a hypothetical binary system, Acta Mater., 2004, vol. 52, no. 5, pp. 1193-1200.
33.    M. Danielewski, B. Wierzba, A. Gusak, M. Pawełkiewicz, J. Janczak-Rusch, Chemical interdiffusion in binary systems; interface barriers and phase competition, J. Appl. Phys., 2011, vol. 110, no. 12, art. no. 123705.
34.    J. Svoboda, F.D. Fischer, Incorporation of vacancy generation/annihilation into reactive diffusion concept - Prediction of possible Kirkendall porosity, Comput. Mater. Sci., 2017, vol. 127, pp. 136-140.
35.    A.V. Nazarov, K.P. Gurov. Kinetic theory of mutual diffusion in a binary system. Concentration of vacancies during mutual diffusion, The Physics of Metals and Metallography, 1974, vol. 37, no. 3, pp. 41-47.
36.    Yu.E. Ugaste, Kinetics of phase growth during mutual diffusion in multiphase binary systems, Physics and Chemistry of Materials Treatment, 1979, no. 3, pp.125-131 (in Russian).
37.    A.G. Knyazeva, M.A. Anisimova, E.N. Korosteleva, Features of diffusion-controlled processes of regulated volumetric synthesis from powder mixtures Ti-Al-Fe-Fe2O3, PNRPU Mechanics Bulletin, 2022, no. 3, pp. 125-134.
38.    E.N. Korosteleva, A.G.Knyazeva, M.A. Anisimova, I.O. Nikolaev, The impact of impurities on the Al-Fe-C system phase composition changes during sintering, Powder Metallurgy and Functional Coatings, 2023, vol. 17, no. 2, pp. 5-13.
39.    M.A. Anisimova, A.G.Knyazeva, E.N. Korosteleva, I.O. Nikolaev, Phase formation during composite synthesis under conditions of reactive sintering of the Ti+Al+Fe2O3+(Fe+C) powder mixture, Izvestiya Vuzov. Fizika, 2023, vol. 66, no 11, pp. 7-16 (in Russian).
40.    Y. Zhao, Y. Chen, S. Ai, D. Fang, A diffusion, oxidation reaction and large viscoelastic deformation coupled model with applications to SiC fiber oxidation, Int. J. Plast., 2019, vol. 118, pp. 173-189.
41.    B.E. Deal, A.S. Grove, General relationship for the thermal oxidation of silicon, J. Appl. Phys., 1965, vol.36, no. 12, pp. 3770-3778.
42.    M. Wilson, E. Opila, A review of SiC fiber oxidation with a new study of Hi-Nicalon SiC fiber oxidation, Adv. Eng. Mater., 2016, vol. 18, no. 10, pp. 1698-1709.
43.    W.L. Wang, S. Lee; J.R. Chen, Effect of chemical stress on diffusion in a hollow cylinder, J. Appl. Phys., 2002, vol. 91, no. 12, pp. 9584-9590.
44.    H. Haftbaradaran, J. Song, W.A. Curtin, H. Gao, Continuum and atomistic models of strongly coupled diffusion, stress, and solute concentration, J. Power Sources, 2011, vol. 196, no. 1, pp. 361-370.
45.    Z. Erdélyi, G. Schmitz, Reactive diffusion and stresses in spherical geometry, Acta Mater., 2012, vol. 60, no. 4, pp. 1807-1817.
46.    M. Roussel, Z. Erdélyi, G. Schmitz, Reactive diffusion and stresses in nanowires or nanorods, Acta Mater., 2017, vol. 131, pp. 315-322.
47.    B.L. Hess, J.J. Ague, Diffusion-induced stress in crystals: Implications for timescales of mountain building, Lithos, 2024, vol. 488-489, art. no. 107783.
48.    B.L. Hess, J.J. Ague, Modeling diffusion in ionic, crystalline solids with internal stress gradients, Geochim. Cosmochim. Acta, 2023, vol. 354, pp. 27-37.
49.    H. Yang, F. Fan, W. Liang, X. Guo, T. Zhu, S. Zhang, A chemo-mechanical model of lithiation in silicon, J. Mech. Phys. Solids, 2014, vol. 70, pp. 349-361.
50.    D. Clerici, F. Mocera, A. Somà, Analytical Solution for Coupled Diffusion Induced Stress Model for Lithium-Ion Battery, Energies, 2020, vol. 13, no.7, art. no. 1717.
51.    I.V. Belova, G.E. Murch, Thermal and diffusion-induced stresses in crystalline solids, J. Appl. Phys., 1995, vol. 77, no. 1, pp. 127-134.
52.    R. Deshpande, Y.-T. Cheng, M.W. Verbrugge, Modeling diffusion-induced stress in nanowire electrode structures, J. Power Sources, 2010, vol. 195, no. 15, pp. 5081-5088.
53.    Z. Guo, T. Zhang, H. Hu, Y. Song, J. Zhang, Effects of Hydrostatic Stress and Concentration-Dependent Elastic Modulus on Diffusion-Induced Stresses in Cylindrical Li-Ion Batteries, J. Appl. Mech., 2014, vol. 81, no. 3, art. no. 031013.
54.    J.L. Chu, S. Lee, The effect of chemical stresses on diffusion, J. Appl. Phys., 1994, vol. 75, no. 6, pp. 2823-2829.
55.    Ya.S. Podstrigach, Diffusion theory of the anelasticity of metals, J. Appl. Mech. Tech. Phys., 1965, vol. 6, pp. 56-60.
56.    F.C. Larche, J.W. Cahn, The effect of self-stress on diffusion in solids, Acta Metall., 1982, vol. 30, no. 10, pp. 1835-1845.
57.    F.C. Larche, J.W. Cahn, The Interactions of Composition and Stress in Crystalline Solids, Journal of Research of the National Bureau of Standards, 1984, vol. 89, no.6, pp. 467-500.
58.    F.C. Larche, J.W. Cahn, Thermochemical equilibrium of multiphase solid under stress, Acta Metall., 1987, vol. 26, no. 10, pp. 1579-1589.
59.    E.C. Aifantis, On the problem of diffusion in solids, Acta Mech., 1980, vol. 37, pp. 265-296.
60.    V.S. Eremeev, Diffusion and Stresses, Energoatomizdat, Moscow, 1984 (in Russian).
61.    J.-L. Grosseau-Poussard, B. Panicaud, S. Ben Afia, Modelling of stresses evolution in growing thermal oxides on metals. A methodology to identify the corresponding mechanical parameters, Comput. Mater. Sci., 2013, vol. 71, pp. 47-55.
62.    Sh. Geng, K. Zhang, B. Zheng, Yu. Zhang, Effects of concentration-dependent modulus and external loads on Li-ion diffusion and stress distribution in a bilayer electrode, Acta Mech., 2024, vol. 235, pp. 191-201.
63.    Z. Cui, F. Gao, J. Qu, A finite deformation stress-dependent chemical potential and its applications to lithium ion batteries, J. Mech. Phys. Solid., 2012, vol. 60, no. 7, pp. 1280-1295.
64.    J.L. Bouvard, D.K. Francis, M.A. Tschopp, E.B. Marin, D.J. Bammann, M.F. Horstemeyer, An internal state variable material model for predicting the time, thermomechanical, and stress state dependence of amorphous glassy polymers under large deformation, Int. J. Plast., 2013, vol. 42, pp. 168-193.
65.    X. Zhang, Q.J. Wang, H. Shen, A multi-field coupled mechanical-electric-magnetic-chemical-thermal (MEMCT) theory for material systems.Comput. Method Appl. Mech. Eng., 2018, vol. 341, pp. 133-162.
66.    X. Zhang, Z. Zhong, A coupled theory for chemically active and deformable solids with mass diffusion and heat conduction, J. Mech. Phys. Solids, 2017, vol. 107, pp. 49-75.
67.    I. Gyarmati, Non-equilibrium Thermodynamics. Field Theory and Variational Principles, Springer-Verlag, Berlin, 1970.
68.    S.R. De Groot, P. Mazur, Non-Equilibrium Thermodynamics, Dover, New York, 1984.
69.    R. Haase, Thermodynamics of Irreversible Processes, Dover, New York, 1969.
70.    W. Liu, S. Shen, Coupled chemomechanical theory with strain gradient and surface effects. Acta Mech., 2018, vol. 229, pp. 133-147.
71.    G. Rambert, J. Grandidier, E. Aifantis, On the direct interactions between heat transfer, mass transport and chemical processes within gradient elasticity, Eur. J. Mech. A, 2007, vol. 26, no. 1, pp. 68-87.
72.    K.P. Frolova, E.N. Vilchevskaya, V.A. Polyanskiy, Yu.A. Yakovlev, Modeling the skin effect associated with hydrogen accumulation by means of the micropolar continuum, Contin. Mech. Thermodyn., 2021, vol. 33, pp. 697-711.
73.    P. Grigoreva, E.N. Vilchevskaya, W.H. Müller, Stress and Diffusion Assisted Chemical Reaction Front Kinetics in Cylindrical Structures, in: H. Altenbach, H. Irschik, V. Matveenko (Eds.), Contributions to Advanced Dynamics and Continuum Mechanics. Advanced Structured Materials, vol 114, Springer, Cham, 2019, pp 53-72.
74.    A.B. Freidin, I.K. Korolev, S.P. Aleshchenko, E.N. Vilchevskaya, Chemical affinity tensor and chemical reaction front propagation: theory and FE-simulations.Int. J. Fract., 2016, vol. 202, pp. 245-259.
75.    A.B. Freidin, I.K. Korolev, E.N. Vilchevskaya, Stress-assist chemical reactions front propagation in deformable solids, Int. J. Eng. Sci., 2014, vol. 83, pp. 57-75.
76.    A. Gusak, N. Storozhuk, Diffusion-Controlled Phase Transformations in Open Systems, in: A. Paul, S. Divinski (Eds.), Handbook of Solid State Diffusion, vol. 2, Elsevier, Amsterdam, 2017, pp. 37-100.
77.    R.-H. Fan, H.-L. Lu, K.-N. Sun, W.-X. Wang, X.-B Yi, Kinetics of thermite reaction in Al-Fe2O3 system, Thermochim. Acta, 2006, vol. 440, no. 2, pp. 129-131.
78.    H.A. Wriedt, The Al-O (Aluminum-Oxygen) system, Bulletin of Alloy Phase Diagrams, 1985, vol. 6, pp. 548-553.
79.    J.L. Murray, Fe-Al binary phase diagram, in: H. Baker (Ed.), Alloy Phase Diagrams, vol. 3, ASM International, Ohio, 1992, p. 54.
80.    O.K. Goldbeck, Iron-binary phase diagrams, Springer, Berlin, 1982.
81.    S.V. Shukhardin, Binary and Multicomponent Systems Based on Copper, Nauka, Moscow, 1979 (in Russian).
82.    N.P. Lyakishev, Phase Diagrams of Binary Metal System, Metallurgiya, Moscow, 1997.
83.    Y. Nakamura, K. Sumiyama, H. Ezawa, Vapor quenched Fe-Ti alloys: Formation of amorphous phase, and metastable Ti2Fe phase by aging, Hyperfine Interact., 1986, vol. 27, pp. 361-364.
84.    S.K. Misra, M. Kahrizi, K. Singh, N. Venkatramani, D. Bahadur, EPR, X-ray, and magnetization studies of metastable alloys Ti2Fe, Al40Cu10Mn25Ge25 and Al65Cu20Fe15 as prepared by mechanical alloying, J. Magn. Magn. Mater., 1995, vol. 150, no. 3, pp. 430-436.
85.    Y.-Ch. Lin, A.S. Shteinberg, P.J. McGinn, A.S. Mukasyan, Kinetics study in Ti-Fe2O3 system by electro-thermal explosion method, Int. J. Therm. Sci., 2014, vol. 84, pp. 369-378.
86.    B.A. Boley, J.H. Weiner, Theory of Thermal Stresses, Wiley, New York, 1960.
87.    M. Anisimova, A. Knyazeva, Diffusion Interaction Model in Al-Fe2O3 System with Including the Formation of Intermetallic Phases, Interfacial Phenom. Heat Transf., 2024, vol. 12, no. 1, pp. 75-88.
88.    V.N. Antsiferov, V.G. Gilev, The role of bulk and mass effects of reactions in reaction sintering processes, Powder Metallurgy and Functional Coatings, 2015, no. 4, pp. 9-20.
89.    L.N. Larikov, Mechanisms of reactive mutual diffusion (review), Metallofiz. Noveishie Tekhnologii, 1994, vol. 16, no. 9, pp. 3-27.
90.    V.I. Arkharov, On the kinetics of reaction diffusion in systems with several intermediate phases, Physics of Metals and Metallography, 1959, vol. 8, no. 2, pp. 193-204.

Том 6, № 3

Страницы 132-156

Файлы

текст статьи

аннотация

XML файл

История

Поступила в редакцию: 21 Сентября 2024

Принята: 28 Сентября 2024

Доступна онлайн: 30 Сентября 2024

© 2024 ITMO University.
This is an open access article under the terms
of the CC BY-NC 4.0 license.
Metadata is available under the terms of the CC BY 4.0 license

Напряжения в локальных объемах при реактивном спекании порошковой смеси Ti-Al-Fe-Fe2O3

Авторы

Аннотация

Ключевые слова

Финансирование

Напряжения в локальных объемах при реактивном спекании порошковой смеси Ti-Al-Fe-Fe₂O₃