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Aviation materials and technologies №1, 2026

Contents

Heat-resistant alloys and steels

  • O.N. Bityutskaya, N.V. Petrushin, V.V. Avdeev, A.R. Narsky

    PRODUCTION OF CASTINGS FOR UNCOOLED TURBINE BLADES FROM SUPERALLOY VZhL21

     

    5-16
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
  • M.D. Panteleev, A.V. Sviridov, A.Yu. Stelnikovich, S.D. Zotov, N.A. Kurnikov, E.A. Pigalova

    FEATURES OF WIRE ARC ADDITIVE MANUFACTURING FOR SYNTHESIS OF VNS-2 (EP410U-SH) STEEL PARTS

    17-27
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
  • D.Yu. Nefedkin, G.S. Sevalnev, A.V. Doroshenko, S.V. Oidinskaya, E.V. Zinoveva, A.A. Gavrilova

    ANALYSIS OF MAGNETIC PROPERTIES OF 21NKMT MARAGING STEEL AFTER VARIOUS TREATMENTS

    28-42
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf

Light-metal alloys

  • A.V. Lavrov

    INVESTIGATION OF HARDENING MODES OF SAMPLES FROM SHEETS OF ALLOY 1163-AT BY FATIGUE HARDENING

    43-52
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
  • Yu.V. Reshetnikov, A.V. Trapeznikov, K.A. Vlasova, A.A. Leonov

    PROSPECTS OF THE USE ALUMINUM FOR BATTERIES

    53-65
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
  • N.P. Cherezov, M.I. Alymov

    AN EFFECTIVE METHOD OF PRODUCING TITANIUM POWDER FROM CHIPS BY COMBINING METHODS OF SELF-PROPAGATING HIGH-TEMPERATURE SYNTHESIS AND THERMAL DEHYDROGENATION

    66-77
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf

Composite materials

  • A.Yu. Kolmogorov, O.Yu. Sorokin, I.O. Belyachenkov, S.A. Evdokimov, M.L. Vaganova

    STUDY OF THE INFLUENCE OF DISPERSED COMPOSITION AND AMOUNT OF FILLER ON THE PHYSICAL AND MECHANICAL PROPERTIES OF GLASS-CERAMIC COMPOSITE MATERIAL 

    78-88
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
  • I.V. Blinkov, O.Yu. Sorokin, B.Yu. Kuznetsov, I.I. Vlasov, S.A. Evdokimov, D.M. Tkalenko, V.A. Prokofiev

    OPTIMIZATION OF THE COMPOSITION AND STRUCTURE OF MULTILAYER METAL-CERAMIC COMPOSITIONAL MATERIAL

    89-102
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
  • N.E. Shchegoleva, V.A. Prokofyev, M.L. Vaganova, A.S. Chainikova, N.S. Moiseeva

    PRODUCTION OF DENSE ALUMINUM OXIDE-BASED CERAMICS

    103-112
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
  • Yu.E. Lebedeva, A.V. Butuzov, M.V. Turchenko, K.I. Svetogorov, A.S. Chainikova, P.B. Mazalov, M.L. Vaganova

    FABRICATION OF ALUMINA-BASED CERAMICS USING STEREOLITHOGRAPHY

    113-125
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
  • Ju.A. Balinova, E.V. Stepanova, A.A. Lugovoy, E.S. Bondarenko

    THERMOLUMINESCENCE OF REFRACTORY OXIDES

    126-144
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
  • A.V. Khokhlov, E.I. Nakonechnyi, S.N. Galyshev, B.I. Atanov, V.I. Orlov, M.V. Zhidkov, V.V. Gulin

    ANALYSIS OF THE PULL-OUT LENGTH DISTRIBUTIONS ON FRACTURE SURFACES OF THE ALUMINUM MATRIX COMPOSITES REINFORCED WITH CONTINUOUS CARBON FIBERS BASED ON SEM AND CLSM DATA

    158-194
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
  • V.N. Strelnikov, E.V. Ivanova, Е.А. Lebedeva, D.K. Trukhinov, S.А. Astafeva

    DEVELOPMENT AND RESEARCH OF THE PROPERTIES OF THERMOPLASTIC ELASTOMER COMPOSITES WITH FUNCTIONAL FILLERS

    195-208
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
  • I.V. Sudzhanskaya

    METHODS OF SYNTHESIS, PROPERTIES, AND APPLICATION OF MgAl2O4 SPINEL

    145-157
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf

Protective and functional coatings

  • V.A. Kuznetsova, S.A. Marchenko, E.A. Timoshina, V.G. Zhelesnyak

    THE FIRMINESS OF PAINT COATINGS TO HYDROABRASIVE EROSION

    209-218
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
  • K.E. Zakharov, M.A. Koltsova, N.S. Lavrov, Yu.N. Nefedova

    STUDY OF THE FORMATION OF NON-METALLIC INORGANIC COATINGS OBTAINED ON SAS1 ALUMINUM ALLOY 

    219-231
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
  • А.А. Аndronov, D.B. Zolotukhin, S.А. Salnikov, А.V. Tyunkov, Yu.G. Yushkov

    PROSPECTS OF USING GADOLINIUM ZIRCONATE AS A CERAMIC LAYER OF THERMAL PROTECTIVE COATING (review)

    232-254
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf

Material tests

  • A.S. Boychuk, I.A. Dikov, A.S. Generalov, S.I. Yakovleva

    NON-DESTRUCTIVE TESTING OF RADIUS ZONES IN MONOLITHIC CARBON FIBER REINFORCED PLASTIC (CFRP) STRUCTURES USING ULTRASONIC PHASED ARRAYS

    255-266
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
  • A.A. Krivushina, A.B. Laptev

    METHODS FOR TESTING THE EFFICIENCY OF BIOCIDAL AGENTS (review)

    267-278
    https://journal.viam.ru/sites/default/files/uploads/contents/2026/2026_1_content.pdf
Содержание номера
1.

DOI: 10.18577/2713-0193-2026-0-1-5-16

UDC: 621.74:669.018.44:669.245

Pages:: 5-16

O.N. Bityutskaya1, N.V. Petrushin1, V.V. Avdeev1, A.R. Narsky1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

PRODUCTION OF CASTINGS FOR UNCOOLED TURBINE BLADES FROM SUPERALLOY VZhL21

 

The NRC «Kurchatov Institute» – VIAM has developed technological processes for producing turbine blade castings from a new generation heat-resistant nickel superalloy VZhL21. Successful testing of the VZhL21 alloy in cooperation with an industrial enterprise for manufacturing turbine blade castings of various nomenclature using the developed technologies demonstrated its potential for producing castings of critical parts designed for long-term operation at temperatures up to 1050 °C in the advanced engines to meet specified weight and performance characteristics.

Keywords:  superalloy, blades, gas turbine engine, polycrystalline structure, mechanical properties, equiaxed casting

Reference List

    1. Kishkin S.T., Lashko N.F., Shpunt K.Ya. et al. Cast heat-resistant nickel alloys VZhL12U and ZhS6U for cooled gas turbine engine blades. S.T. Kishkin. Development, Research, and Application of Heat-Resistant Alloys: Selected Works. Moscow: Nauka, 2006, pp. 272–276.
    2. Stepanov V.M., Kishkin S.T., Chumakov V.A. et al. Advanced Methods of Precision Casting of Gas Turbine Engine Blades. S.T. Kishkin. Development, Research, and Application of Heat-Resistant Alloys: Selected Works. Moscow: Nauka, 2006, pp. 304–310.
    3. Cast blades of gas turbine engines: alloys, technologies, coatings. Ed. E.N. Kablov. 2nd ed. Moscow: Nauka, 2006, 632 p.
    4. Logunov A.V., Bykov Yu.G. Problems of Design and Production of High-Temperature Cast Blades for Aircraft Gas Turbine Engines: in 2 books. Moscow: Nauka i Tekhnologii, 2023, book 2: Technology and Production, 640 p.
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    8. Petrushin N.V., Ospennikova O.G., Rassokhina L.I., Bityutskaya O.N. New-Generation Cast Heat-Resistant Alloy VZhL21 with a Polycrystalline Structure. Liteyshchik Rossii, 2014, no. 6, pp. 40–46.
    9. Aviation Materials: Handbook in 13 vols. 7th Revised and Supplemented Edition. Ed. E.N. Kablov. Moscow: NRC «Kurchatov Institute» – VIAM, 2022, vol. 3: Casting Heat-Resistant and Intermetallic Nickel-Based Alloys, 192 p.
    10. Gabb T.P., Dreshfill R.L. Properties of Superalloys. Superalloys II. Heat-Resistant Materials for Aerospace and Industrial Power Plants. Eds. C.T. Sims, N.S. Stoloff, W.K. Hagel; translated from English: in 2 books. Moscow: Metallurgy, 1995, book 2, pp. 352–371.
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    12. Petrushin N.V., Visik E.M., Elyutin E.S. Improvement of the chemical composition and structure of castable nickel-base superalloy with low density. Part 2. Trudy VIAM, 2021, no. 4 (98), pp. 3–15. Available at: http://www.viam-works.ru (accessed: December 18, 2024). DOI: 10.18577/2307-6046-2021-0-4-3-15.
    13. Ospennikova O.G. Tendencies of development of heat-resistant nickel alloys of low density with polycrystalline and single-crystal structures (review). Aviacionnye materialy i tehnologii, 2016, no. 1 (40), pp. 3–19. DOI: 10.18577/2071-9140-2016-0-1-3-19.
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    15. Kablov E.N. VIAM Developments for Gas Turbine Engines and Installations. Krylya Rodiny, 2010, no. 4, pp. 31–33.
    16. Polyansky V.M., Gavrilyuk V.V., Zagorsky V.Z. et al. Structure, Properties, and Fracture Mechanism of Nickel-Based Heat-Resistant Casting Alloy. Metallovedenie i termicheskaya obrabotka metallov, 2004, no. 9, рp. 32–36.
    17. Ross I.V., Sims C.T. Nickel-Based Alloys. Superalloys II. Heat-Resistant Materials for Aerospace and Industrial Power Plants. Eds. C.T. Sims, N.S. Stoloff, W.K. Hagel; translated from English: in 2 books. Moscow: Metallurgy, 1995, book 1, pp. 128–174.
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    22. Kablov E.N., Echin A.B., Bondarenko Yu.A. History of development of directional crystallization technology and equipment for casting blades of gas turbine engines. Trudy VIAM, 2020, no. 3 (87), pp. 3–12. Available at: http://www.viam-works.ru (accessed: December 18, 2024). DOI: 10.18577/2307-6046-2020-0-3-3-12.
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    27. Orlov M.R. Analytical assessment of the kinetics of pore elimination in cast turbine blades during hot isostatic pressing. Metallovedeniye i termicheskaya obrabotka metallov, 2009, no. 2 (644), pp. 17–20.

Full version
2.

DOI: 10.18577/2713-0193-2026-0-1-17-27

UDC: 669.14

Pages:: 17-27

M.D. Panteleev1, A.V. Sviridov1, A.Yu. Stelnikovich1, S.D. Zotov1, N.A. Kurnikov2, E.A. Pigalova2

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»
[2] Nizhny Novgorod aircraft building plant «SOKOL» – Branch of Public Joint Stock Company «United Aircraft Corporation»

FEATURES OF WIRE ARC ADDITIVE MANUFACTURING FOR SYNTHESIS OF VNS-2 (EP410U-SH) STEEL PARTS

The article presents successful application of VNS-2 (EP410U-Sh) steel in the form of welding wire in additive manufacturing for synthesis of parts by the wire arc additive manufacturing (WAAM). The dependences between geometrical and energetic parameters in different dimensional positions are presented. The mechanical properties of samples received after thermal processing under different synthesis direction strategies has been defined. The comparative analysis of mechanical properties of samples obtained using additive and traditional technologies is discussed.

Keywords: corrosion steel, VNS-2, EP410U-Sh, additive technologies, wire arc additive manufacturing, mechanical properties

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    2. Korobova E.N., Sevalnev G.S., Gromov V.I., Leonov A.V. Steels for the manufacture of roller bearings for special purposes (review). Trudy VIAM, 2021, no. 11 (105), pp. 3–11. Available at: http://www.viam-works.ru (accessed: December 08, 2024). DOI: 10.18577/2307-6046-2021-0-11-3-11.
    3. Bogachev I.A., Sulyanova E.A., Sukhov D.I., Mazalov P.B. Microstructure and properties investigations of Fe–Cr–Ni stainless steel obtained by selective laser melting. Trudy VIAM, 2019, no. 3 (75), pp. 3–13. Available at: http://www.viam-works.ru (accessed: December 08, 2024). DOI: 10.18577/2307-6046-2019-0-3-3-13.
    4. Voznesenskaya N.M., Tonysheva O.A., Eliseev E.A. Modern structural steels of cryogenic purpose and influence of some alloying elements on their properties (review). Trudy VIAM, 2020, no. 1, pp. 3–14. Available at: http://www.viam-works.ru (accessed: December 03, 2024). DOI: 10.18577/2307-6046-2020-0-1-3-14.
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Full version
3.

DOI: 10.18577/2713-0193-2026-0-1-28-42

UDC: 631.437.8

Pages:: 28-42

D.Yu. Nefedkin1, G.S. Sevalnev1, A.V. Doroshenko1, S.V. Oidinskaya2, E.V. Zinoveva2, A.A. Gavrilova2

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»
[2] Bauman Moscow State Technical University (National Research University of Technology

ANALYSIS OF MAGNETIC PROPERTIES OF 21NKMT MARAGING STEEL AFTER VARIOUS TREATMENTS

The magnetic properties of 21NKMT maraging steel after various types of processing have been analyzed. The applicability of magnetization methods for ring-shaped specimens according to GOST 8.377‒80 and the Shteblein method for measuring the properties of 21NKMT steel was evaluated. It was determined that 21NKMT steel exhibits the properties of a soft magnetic  material after hot deformation, annealing and quenching, as well as after aging at temperatures up to 550 °C. The changes in the magnetic properties of 21NKMT steel at different stages of heat treatment used in the manufacturing of resonators for solid-state wave gyroscopes have been studied.

Keywords: 21NKMT maraging steel, magnetic properties, elastic properties, Q-factor of mechanical vibrations, wave solid-state wave gyroscope

Reference List

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Full version
4.

DOI: 10.18577/2713-0193-2026-0-1-43-52

UDC: 621.787

Pages:: 43-52

A.V. Lavrov1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

INVESTIGATION OF HARDENING MODES OF SAMPLES FROM SHEETS OF ALLOY 1163-AT BY FATIGUE HARDENING

The article presents the results of a study of the influence of some parameters of the fatigue hardening mode on the life to failure of samples made of 1163-AT alloy sheets. The mechanical properties of the sheets in the initial state are given, the technique of their treatment by the fatigue hardening method is described. The results of fatigue tests of hardened samples, including their fatigue curves and photographs of their fractures are given. The influence of the fatigue test mode parameters on the results of fatigue tests is considered. It is shown that one of the main factors influencing the hardening process can be the presence of a cladding layer.

Keywords: surface plastic deformation, fatigue hardening, fatigue testing, fatigue strength, strain hardening, fatigue fracture

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Full version
5.

DOI: 10.18577/2713-0193-2026-0-1-53-65

UDC: 669.71

Pages:: 53-65

Yu.V. Reshetnikov1, A.V. Trapeznikov1, K.A. Vlasova1, A.A. Leonov1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

PROSPECTS OF THE USE ALUMINUM FOR BATTERIES

The article summarizes the studies of aluminum as a promising material for battery production: a comparison with various electrochemical energy storage systems is made and the main development tasks are defined. Aluminum is of great interest from the point of view of battery production due to its low cost, high volumetric and gravimetric capacity. A large number of electrochemical systems based on aluminum have been developed. The widespread adoption of aluminum-based batteries is constrained by insufficient study of its electrochemical behavior.

Keywords: aluminum, lithium, accumulator, battery, aluminum-ion accumulator, aluminum-sulfur accumulator, aluminum-air batteries

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Full version
6.

DOI: 10.18577/2713-0193-2026-0-1-66-77

UDC: 669.295

Pages:: 66-77

N.P. Cherezov1, M.I. Alymov1

[1] Merzhanov Institute of Structural Macrokinetics and Materials Science RAS

AN EFFECTIVE METHOD OF PRODUCING TITANIUM POWDER FROM CHIPS BY COMBINING METHODS OF SELF-PROPAGATING HIGH-TEMPERATURE SYNTHESIS AND THERMAL DEHYDROGENATION

Efficient recycling of titanium production waste, in particular chips, is one of the key challenges for the titanium industry. This paper describes a new process for the recycling of titanium chips based on the SHS-hydrogenation technology followed by thermal dehydrogenation. The hydrogenation was carried out in a closed reactor in the wave combustion mode with an initial hydrogen pressure of 2,5 MPa and an operating pressure of at least 1 MPa. A SHS-hydrogenation scheme was developed to convert the chips to titanium hydride TiH2. The resulting hydride was mechanically crushed and the powder was then subjected to thermal dehydrogenation in a vacuum furnace to remove hydrogen. Due to the energy efficiency of the SHS method and the use of cheap raw materials (chips), it was possible to obtain titanium powder in a fragmented form with a particle size of 20–80 microns, an acceptable level of impurities and low cost. However, further research is needed to optimize the process and improve the quality of the final product.

Keywords: titanium powder, titanium chips, titanium waste recycling, hydrogen, SHS-hydrogenation, thermal dehydrogenation

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Full version
7.

DOI: 10.18577/2713-0193-2026-0-1-78-88

UDC: 620.1

Pages:: 78-88

A.Yu. Kolmogorov1, O.Yu. Sorokin1, I.O. Belyachenkov1, S.A. Evdokimov1, M.L. Vaganova1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

STUDY OF THE INFLUENCE OF DISPERSED COMPOSITION AND AMOUNT OF FILLER ON THE PHYSICAL AND MECHANICAL PROPERTIES OF GLASS-CERAMIC COMPOSITE MATERIAL 

The influence of the dispersed composition and amount of filler on the physical and mechanical properties of glass-ceramic composite material based on silicon carbide was studied. The optimal dispersed composition of the filler was determined, the optimal mixing time of the SiC powder mixture was experimentally determined, and data on the physical and mechanical characteristics of the samples of glass-ceramic composite material based on silicon carbide were obtained. It was established that SiC ceramic composite can be obtained at temperatures up to 1000 °С.

Keywords: silicon carbide, composite material, glass-ceramics, dispersed composition, non-brittle fracture, matrix, glass binder, glass system, fractional composition

Reference List

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Full version
8.

DOI: 10.18577/2713-0193-2026-0-1-89-102

UDC: 666.3

Pages:: 89-102

I.V. Blinkov1, O.Yu. Sorokin2, B.Yu. Kuznetsov2, I.I. Vlasov2, S.A. Evdokimov2, D.M. Tkalenko2, V.A. Prokofiev2

[1] National University of Science and Technology «MISIS»
[2] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

OPTIMIZATION OF THE COMPOSITION AND STRUCTURE OF MULTILAYER METAL-CERAMIC COMPOSITIONAL MATERIAL

The paper presents the results of computer modeling by the finite element method of the mechanism of destruction of metal-ceramic composite material under three-point bending. The processes of structure and phase formation at the interface of «refractory metal‒alloy of the Mo–Si–B system» are studied to optimize the composition and structure of high-temperature metal-ceramic composite material with a multilayer structure. The influence of the interphase boundary structure on a number of basic physical and mechanical properties is established.

Keywords: ceramics, composite material, multilayer structure, crack resistance, mechanical properties, finite element method, elasticity model, plasticity model

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    16. Sudin Yu.I., Salakhova R.K., Galiullin An.R., Savitsky R.S. Study of surface-energy characteristics of elements of three-layer honeycomb panels. Trudy VIAM, 2024, no. 12 (142), pp. 66–74. Available at: http://www.viam-works.ru (accessed: June 27, 2025). DOI: 10.18577/2307-6046-2024-0-12-66-74.

Full version
9.

DOI: 10.18577/2713-0193-2026-0-1-103-112

UDC: 666.3-16

Pages:: 103-112

N.E. Shchegoleva1, V.A. Prokofyev1, M.L. Vaganova1, A.S. Chainikova1, N.S. Moiseeva1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

PRODUCTION OF DENSE ALUMINUM OXIDE-BASED CERAMICS

Samples of ceramic material based on aluminum oxide nanopowder with the use of sintering additives of magnesium-aluminosilicate composition were produced by semi-dry pressing followed by high-temperature sintering. The influence of the sintering additive, technological binder and temperature-time sintering regime on the phase composition, density and porosity of ceramics was studied. It was shown that ceramic samples produced using a sintering additive in the form of a mixture of magnesium, aluminum, and silicon oxides containing yttrium oxide as a modifier are characterized by higher density.

Keywords: aluminum oxide-based ceramics, sintering additive, phase composition, density, strength, microhardness, crack resistance

Reference List

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Full version
10.

DOI: 10.18577/2713-0193-2026-0-1-

UDC: 666.3

Pages:: 113-125

Yu.E. Lebedeva1, A.V. Butuzov1, M.V. Turchenko1, K.I. Svetogorov1, A.S. Chainikova1, P.B. Mazalov1, M.L. Vaganova1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

FABRICATION OF ALUMINA-BASED CERAMICS USING STEREOLITHOGRAPHY

The potential of laser stereolithography for producing alumina ceramic products is explored. A highly filled (≥80 % by weight) photocurable alumina-based ceramic paste has been developed. This paste enables the production of complex-shaped alumina ceramic parts via laser stereolithography with properties comparable to the best structural counterparts produced by conventional methods: density of 3,6–3,9 g/cm3, flexural strength of 233–312 MPa, hardness of 15,3 GРa, stress intensity coefficient of 5,9 MPa , as well as parts made of porous ceramics.

Keywords: 3D printing, laser stereolithography, alumina ceramics, additive technologies, ceramic pastes, dense ceramics

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    2. Lebedeva Yu.E., Shchegoleva N.E., Voronov V.A., Solntcev S.S. Al2O3 and ZrO2 ceramic materials obtained by sol-gel method. Trudy VIAM, 2021, no. 4 (98), pp. 61–73. Available at: http://www.viam-works.ru (accessed: April 08, 2025). DOI: 10.18577/2307-6046-2021-0-4-61-73.
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Full version
11.

DOI: 10.18577/2713-0193-2026-0-1-126-144

UDC: 677.523

Pages:: 126-144

Ju.A. Balinova1, E.V. Stepanova1, A.A. Lugovoy1, E.S. Bondarenko1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

THERMOLUMINESCENCE OF REFRACTORY OXIDES

The publication presents the analysis of scientific and technical researches in the field of thermally induced luminescence of refractory oxides doped with rare earth elements. The conditions of thermostimulated luminescence phenomenon are considered. There presented characteristics of thermally induced luminescence spectra for alumina, yttria, zirconia, hafnium, and gadolinia matrixes. It is shown that hafnium oxide is the most promising matrix material for special optics and microelectronics. Lanthanides are the most promising additives imparting luminescence properties to oxide matrix

Keywords: thermoluminescence, refractory oxides, rare earth elements, lanthanides, energy sublevel, up-conversion, spectra

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Full version
12.

DOI: 10.18577/2713-0193-2026-0-1-145-157

UDC: 546.05:666.3.16

Pages:: 145-157

I.V. Sudzhanskaya1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

METHODS OF SYNTHESIS, PROPERTIES, AND APPLICATION OF MgAl2O4 SPINEL

Magnesium aluminate spinel is a material with an excellent combination of mechanical properties, chemical resistance, and optical transparency, which makes it promising for in the production of optically transparent windows, refractories, medical products, etc. The article covers scientific and technical literature on the synthesis methods, properties and application of MgAl2O4 spinel. It is shown that reducing the grain size, combining sintering methods, and introducing alloying additives into MgAl2O4 allows for tailoring spinel properties over a wide range, which significantly expands the areas of its application.

Keywords: magnesium aluminate spinel, doping, optical transparency, mechanical properties, density, microhardness, crack resistance

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Full version
13.

DOI: 10.18577/2713-0193-2026-0-1-158-194

UDC: 620.1

Pages:: 158-194

A.V. Khokhlov1, E.I. Nakonechnyi1, S.N. Galyshev2, B.I. Atanov2, V.I. Orlov2, M.V. Zhidkov3, V.V. Gulin1

[1] Institute of Mechanics, Lomonosov Moscow State University
[2] Osipyan Institute of Solid State Physics RAS
[3] Federal Research Center of Problems of Chemical Physics and Medicinal Chemistry RAS

ANALYSIS OF THE PULL-OUT LENGTH DISTRIBUTIONS ON FRACTURE SURFACES OF THE ALUMINUM MATRIX COMPOSITES REINFORCED WITH CONTINUOUS CARBON FIBERS BASED ON SEM AND CLSM DATA

The fracture surface properties under tensile loading have been investigated for a series of high-strength unidirectional composites with an aluminum matrix alloyed with bismuth and continuously reinforced with carbon fibers (with a fiber volume fraction of up to 60–65 %). These composites were produced at the experimental facility of the Institute of Solid State Physics (Russian Academy of Sciences) by drawing 1000 filament carbon fiber tows through the molten matrix at varying speeds ranging from 2 to 16 mm/s. To analyze the distributions of local surface heights and fiber pull-out lengths, a set of original algorithms for automated processing and integrated analysis of scanning electron microscopy (SEM) and confocal laser scanning microscopy (CLSM) data was employed. These algorithms were applied to complex fracture surfaces of fiber-reinforced composites with parallel fiber alignment. The developed methods allow extraction of a wide array of important quantitative characteristics from rough fracture surfaces with large height gradients. These characteristics are instrumental for evaluating (and tuning) the interfacial properties, the fracture energy components, and the strength of the composite, as well as for understanding the failure mechanisms, assessing their impact on strength, and supporting modeling efforts. The key idea and novelty of the proposed methodology and its software implementation lies in the combined use of two complementary high-resolution microscopy techniques and in the joint analysis of fracture surfaces from both complementary halves of a specimen fractured under bending or tensile load. This approach significantly increases the volume of extractable data compared to separate images, enabling the reconstruction of features hidden due to complex topography in one half using information from the other. As a result, it ensures high precision and robustness in detecting structural contours and computing quantitative features. The study examines the influence of fiber tow drawing time through the matrix melt on the stress-strain behavior, fracture surface topography of CF/Al–0,5Bi composites, and the statistical characteristics of fiber pull-out length distributions.

Keywords: unidirectional composites, metal matrix composites, weak interface, carbon fibers, fracture surface microstructure, scanning electron microscopy (SEM), confocal laser scanning microscopy (CLSM), topography reconstruction, fiber pull-out length distribution, image analysis, fracture work, strength

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Full version
14.

DOI: 10.18577/2713-0193-2026-0-1-195-208

UDC: 678.8

Pages:: 195-208

V.N. Strelnikov1, E.V. Ivanova1, Е.А. Lebedeva1, D.K. Trukhinov1, S.А. Astafeva1

[1] «Institute of Technical Chemistry Ural Branch Russian Academy of Sciences» – Branch of the Perm Federal Research Center Ural Branch Russian Academy of Sciences

DEVELOPMENT AND RESEARCH OF THE PROPERTIES OF THERMOPLASTIC ELASTOMER COMPOSITES WITH FUNCTIONAL FILLERS

Thermoplastic composites based on two grades of thermoplastic styrene-ethylene-butylene-styrene block copolymer modified with functional fillers (chopped carbon fiber and magnetite ore) were obtained. The rheological properties of polymer melt and the mechanical characteristics of the initial and filled thermoplastic elastomer samples produced by injection molding were investigated. The introduction of fillers increases the stiffness of thermoplastic elastomers was found. The thermoplastic composite with a broader molecular weight distribution of the polymer retained greater elasticity upon fillers incorporation were shown. 

Keywords: thermoplastic elastomers, carbon fiber, polymer composite materials, interfacial interaction

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Full version
15.

DOI: 10.18577/2713-0193-2026-0-1-209-218

UDC: 629.7.023.222

Pages:: 209-218

V.A. Kuznetsova1, S.A. Marchenko1, E.A. Timoshina1, V.G. Zhelesnyak1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

THE FIRMINESS OF PAINT COATINGS TO HYDROABRASIVE EROSION

The firmness of systems of erosion-resistant paint coatings (abbr.PC) to hydroabrasive erosion has been studied using sample simulators from D1-T An.Ox.Bichr alloy and VPS-20 fiberglass. The main attention in this work is given to firmness of PC systems on the basis of the fiber-reinforced erosion-resistant coating EP-5236 used for protection of D1-T aluminum alloy of An.Ox.Bichr, and also VPS-20 fiberglass when exposed to hydroabrasive erosion. The highest stability to hydroabrasive erosion shows PC systems based on erosion-resistant EP-5236 enamel compared to EP-0065 + HP-0206 + HP-5184 and EP-0065 + + EP-0104 + FP-5105 + KCh-5185.

Keywords: systems of paint coatings, hydroabrasive erosion, adhesion strength, elasticity, mechanical strength, erosion-resistant coating

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Full version
16.

DOI: 10.18577/2713-0193-2026-0-1-219-231

UDC: 667.6

Pages:: 219-231

K.E. Zakharov1, M.A. Koltsova1, N.S. Lavrov1, Yu.N. Nefedova1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

STUDY OF THE FORMATION OF NON-METALLIC INORGANIC COATINGS OBTAINED ON SAS1 ALUMINUM ALLOY 

The most widely used method for corrosion protection of parts made of aluminium and its alloys is the application of non-metallic inorganic protective coatings – chemical oxide or anodic oxide coatings. Although these coatings are used to protect parts made of both wrought and cast aluminium alloys, the formation of such coatings on alloys with a high silicon content (such as SAS1 alloy)is often problematic. This paper presents the results of research aimed at evaluating the formation of the most common protective coatings used in manufacturing aluminium alloy parts on SAS1 alloy.

Keywords: sintered aluminium alloys, chemical oxide coatings, anodic oxide coatings, corrosion protection, etching of aluminium alloys, brightening of aluminium alloys

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Full version
17.

DOI: 10.18577/2713-0193-2026-0-1-232-254

UDC: 629.7.023.224

Pages:: 232-254

А.А. Аndronov1, D.B. Zolotukhin1, S.А. Salnikov1, А.V. Tyunkov1, Yu.G. Yushkov1

[1] Federal State Autonomous Educationfl Institution of Higher Education – Tomsk State University of Control Systems and Radioelectronics

PROSPECTS OF USING GADOLINIUM ZIRCONATE AS A CERAMIC LAYER OF THERMAL PROTECTIVE COATING (review)

The review discusses the prospects of using a new gadolinium zirconate (Gd2Zr2O7) material as a ceramic layer of a heat-protective coating. A critical review and comparison of the main methods of forming thick ceramic coatings is presented, such as atmospheric plasma spraying, high-speed flame spraying using oxygen, suspension plasma spraying, plasma spraying of precursor solutions, electron beam physical vapor deposition, electron beam deposition in a forevacuum. The results of tests on thermocyclic resistance and thermal conductivity of single-layer, two- and three-layer coatings are presented. The possibility of synthesizing such coatings using forevacuum plasma electron sources is shown.

Keywords: thermal protective coatings, plasma spraying, electron beam deposition, ceramic coatings, forevacuum plasma electron source

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Full version
18.

DOI: 10.18577/2713-0193-2026-0-1-255-266

UDC: 620.179.162

Pages:: 255-266

A.S. Boychuk1, I.A. Dikov1, A.S. Generalov1, S.I. Yakovleva1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

NON-DESTRUCTIVE TESTING OF RADIUS ZONES IN MONOLITHIC CARBON FIBER REINFORCED PLASTIC (CFRP) STRUCTURES USING ULTRASONIC PHASED ARRAYS

The possibility of ultrasonic nondestructive testing of CFRP monolith structures’ radius zones using an ultrasonic method with radius phased arrays was investigated. The article presents the results of inspecting a curved beam specimen using phased arrays with different ways of acoustic contact creation. The results obtained with this technology showed its effectiveness in detecting defects such as fragments of fluoroplastic film inclusions with a diameter of 5 mm.

Keywords: carbon fiber reinforced plastic (CFRP), monolith structures, radius zones, non-destructive testing, ultrasonic methods, phased arrays

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Full version
19.

DOI: 10.18577/2713-0193-2026-0-1-267-278

UDC: 632.937

Pages:: 267-278

A.A. Krivushina1, A.B. Laptev1

[1] Federal state unitary enterprise «All-Russian Scientific-Research Institute of Aviation Materials» of National Research Center «Kurchatov Institute»

METHODS FOR TESTING THE EFFICIENCY OF BIOCIDAL AGENTS (review)

Biocidal agents are chemicals that inhibit the growth and development of microorganisms. Studies of the efficiency of biocides play an important roleare particularly important, as the emergence of microbial resistance can render some commonly used control agents ineffective. The article provides a review of various methods of testing biocidal drugs. The main methods include techniques for determining the biocide efficiency on solid nutrient media (diffusion methods), in liquid media, and on samples of the protected materials.

Keywords: biodeterioration, biocides, fungal resistance, microbiological damage, decomposers, fungicides

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