Strengthening construction materials using nanopowders opens new possibilities for creating stronger, more durable, and sustainable structures. This research direction is actively being explored and developed, enabling the implementation of innovative solutions in the con-struction industry and improving the quality of building materials. To enhance the mechanical, thermal, and other properties of polymeric materials, nanopowders of metal oxides, carbides, graphene, and carbon nanotubes are introduced into the matrix. The use of tungsten-based nanopowders represents a relevant task that, in the long term, can address the limitations of existing technologies and expand the application areas of these compounds for creating new materials. Previously, the use of such particles was economically unfeasible for modify-ing cement and concrete matrices, ceramics, and composites based on aramid and fiberglass fabrics. The aim of this study was to investigate the possibility of using tungsten-containing nanopowders obtained through the processing of hard-alloy waste via a technology that is more economical and simpler compared to existing analogues, and to consider potential applications of these powders as modifiers. Tungsten-containing nanopowders were produced using a patented method that differs from analogues by the high purity of the resulting powder, min-imal production costs, and negligible impact on the natural environment. This article presents possible applications of tungsten-containing nanopowders as modifiers. It is demonstrated that such powders can significantly improve various operational properties of "conventional" construction materials due to their low production cost. This enables the development of innovative materials capable of meeting growing and diverse demands.
nanopowder, tungsten carbide, tungsten oxide, ceramics, concrete, composite, strength, tensile and flexural strength, wear resistance, impact strength, radiation resistance.
1. Stroitel'stvo v rossiyskih regionah: itogi 2025 goda / [Elektronnyy resurs] // sherpagroup.ru : [sayt]. — URL: https://sherpagroup.ru/analytics/3p7pdnr (data obrascheniya: 17.02.2026).
2. Ot tradicionnyh betonov k betonam novogo pokoleniya / V. T. Erofeev, S. V. Samchenko, O. V. Tarakanov [i dr.] // Iz-vestiya vysshih uchebnyh zavedeniy. Seriya Himiya i himiche-skaya tehnologiya. – 2025. – T. 68, № 12. – S. 83-95. – DOIhttps://doi.org/10.6060/ivkkt.20256812.7199. – EDN KBTBYW.
3. Balaguru, P.; Chong, K. Nanotechnology and Concrete: Re-search Opportunities; ACI Special Publication; American Concrete Institute: Farmington Hills, MI, USA, 2008; pp. 15–28. [Google Scholar]
4. Svidetel'stvo o gosudarstvennoy registracii bazy dan-nyh № 2024623430 Rossiyskaya Federaciya. Novye kompo-zicionnye i funkcional'nye stroitel'nye materialy s povyshennymi mehanicheskimi, termicheskimi i fotokata-liticheskimi harakteristikami : № 2024623126 : zayavl. 22.07.2024 : opubl. 06.08.2024 / S. V. Samchenko, A. V. Kor-shunov, I. V. Kozlova [i dr.] ; zayavitel' Federal'noe gosu-darstvennoe byudzhetnoe obrazovatel'noe uchrezhdenie vys-shego obrazovaniya "Nacional'nyy issledovatel'skiy Mos-kovskiy gosudarstvennyy stroitel'nyy universitet". – EDN DHKMMO.
5. Muzenski, S.; Flores-Vivian, I.; Farahi, B.; Sobolev, K. To-wards ultrahigh performance concrete produced with alumi-num oxide nanofibers and reduced quantities of silica fume. Nanomaterials 2020, 10, 2291. [Google Scholar] [CrossRef]
6. Tahmouresi, B.; Nemati, P.; Asadi, M.A.; Saradar, A.; Moh-tasham Moein, M. Mechanical strength and microstructure of engineered cementitious composites: A new configuration for direct tensile strength, experimental and numerical analysis. Constr. Build. Mater. 2021, 269, 121361. [Google Scholar] [CrossRef]
7. Gong, K.; Pan, Z.; Korayem, A.H.; Qiu, L.; Li, D.; Collins, F.; Wang, C.M.; Duan, W.H. Reinforcing effects of graphene oxide on portland cement paste. J. Mater. Civ. Eng. 2015, 27, 1–6. [Google Scholar] [CrossRef]
8. Kozlova, I. V. Nanotehnologii v proizvodstve stroi-tel'nyh materialov: teoreticheskoe issledovanie / I. V. Kozlova, S. V. Samchenko // Tehnika i tehnologiya silikatov. – 2024. – T. 31, № 3. – S. 284-297. – DOIhttps://doi.org/10.62980/2076-0655-2024-284-297. – EDN USMLQM.
9. Rodionov R.B. Nanotehnologii – innovacionnoe napravlenie razvitiya v stroitel'noy industrii / R.B. Ro-dionov // Stroitel'nye materialy, oborudovanie, tehno-logii HHI veka. – 2006. – №9. – S. 62 – 64.
10. Falikman, V.R. Nanomaterialy i nanotehnologii v stroitel'stve: segodnya i zavtra / V.R. Falikman // Stroi-tel'nye materialy, oborudovanie, tehnologii HHI veka. – 2009. -№1. – S. 64 – 68.
11. Korolev, E.V. Nekotorye polozheniya nanotehnologii v stroitel'nom materialovedenii / E.V. Korolev, A.N. Gri-shina // Sb. trudov mezhdunarodnoy nauchnoy konferencii «Integraciya, partnerstvo i innovacii v stroitel'noy nauke i obrazovaniyu – M.: MGSU, 2011. – T.2. – S. 94 – 102.
12. Moses Karakouzian, Visar Farhangi, Marzieh Ramezani Farani, Alireza Joshaghani,Mehdi Zadehmohamad and Mo-hammad Ahmadzadeh Mechanical Characteristics of Cement Paste in the Presence of Carbon Nanotubes and Silica Oxide Nanoparticles: An Experimental Study // Materials 2021, 14(6), 1347; https://doi.org/10.3390/ma14061347
13. Kozlova, I. V. Nanostrukturirovannye kompozicion-nye materialy: formirovanie ranney struktury i proch-nosti / I. V. Kozlova, S. V. Samchenko // Tehnika i tehnolo-giya silikatov. – 2025. – T. 32, № 4. – S. 358-368. – https://doi.org/10.62980/2076-0655-2025-358-368. – EDN TBXCNX.
14. Self-Cleaning Cement Material with Bismuth Titanate Photocatalytic Additive / I. Kozlova, M. Dudareva, O. Zemskova [et al.] // Civil Engineering Journal. – 2025. – Vol. 11, No. 11. – P. 4696-4708. – https://doi.org/10.28991/cej-2025-011-11-014. – EDN HCPBBU.
15. Lastovka, A. V., Danchenko, T. V., Petuhova, I. Ya., Polya-kov, I. A. Nanotehnologii v oblasti proizvodstva betona [Tekst] / A. V. Lastovka, T. V. Danchenko, I. Ya. Petuhova, I. A. Polyakov // Tehnicheskie nauki. Stroitel'stvo. — 2022. — № 2. — S. 338-349.
16. Evtushenko, E.I. Aktivacionnye processy v tehnolo-gii stroitel'nyh materialov / E.I. Evtushenko. – Belgo-rod, 2003. – 209 s.
17. Solov'eva, V.Ya., Stepanova I.V. Razrabotka vysoko-prochnogo betona povyshennoy treschinostoykosti / V.Ya. Solov'eva, I.V. Stepanova // Izvestiya Peterburgskogo universiteta putey soobscheniy. - Spb., 2004. - V. 1. – S. 31-34.
18. Hakimova, E.Sh. Cementnye betony s nanodobavkami sinteticheskogo ceolita / E.Sh. Hakimova // Vestnik YuUr-GU. - 2008. - №25. - C.16-21.
19. Polimernye nanokompozitnye materialy, primery i perspektivy ih ispol'zovaniya / [Elektronnyy resurs] // ElectricalSchool.info : [sayt]. — URL: https://electricalschool.info/guides/2705-polimernye-nanokompozitnye-materialy.html (data obrascheniya: 17.02.2026).
20. Tyurin, A. I. Vliyanie uglerodnyh nanotrubok na prochnostnye svoystva cirkonievoy keramiki na osnove baddeleita pri nano- i mikroindentirovanii / A. I. Tyu-rin, T. S. Pirozhkova // Sovremennye tehnologii i materi-aly novyh pokoleniy : sbornik trudov mezhdunarodnoy konferencii s elementami nauchnoy shkoly dlya molodezhi, Tomsk, 09–13 oktyabrya 2017 goda / Nacional'nyy issledo-vatel'skiy Tomskiy politehnicheskiy universitet. – Tomsk: Nacional'nyy issledovatel'skiy Tomskiy poli-tehnicheskiy universitet, 2017. – S. 218-219. – EDN ZRXDWT.
21. Baruzdin A.A., Zakrevskaya L.V. Dekorativnyy kompozi-cionnyy material na osnove reciklinga othodov sshitogo polietilena i stroitel'noy keramiki// Tehnika i tehno-logiya silikatov. – 2025. – T. 32, № 5. – S.434-445. https://doi.org/10.62980/2076-0655-2026-434-445 , EDN uguwic
22. Issledovanie vliyaniya nanodispersnyh dobavok na iz-meneniya prochnosti betona / V. M. Gavrish, T. V. Chayka, O. P. Gavrish, A. Yu. Oleynik // Perspektivnye tehnologii i materialy : Materialy nauchno–prakticheskoy konferen-cii s mezhdunarodnym uchastiem, Sevastopol', 14–16 ok-tyabrya 2020 goda. – Sevastopol': Federal'noe gosudar-stvennoe avtonomnoe obrazovatel'noe uchrezhdenie vysshe-go obrazovaniya "Sevastopol'skiy gosudarstvennyy uni-versitet", 2020. – S. 129-130. – EDN AUJNXE.
23. Patent № 2414992 C2 Rossiyskaya Federaciya, MPK B22F 9/00, B82B 3/00, C01B 31/34. Sposob polucheniya nanoporoshka karbida vol'frama : № 2009101478/02 : zayavl. 19.01.2009 : opubl. 27.03.2011 / V. A. Arhipov, A. B. Vorozhcov, S. A. Vorozhcov [i dr.] ; zayavitel' Gosudar-stvennoe obrazovatel'noe uchrezhdenie vysshego professi-onal'nogo obrazovaniya Tomskiy gosudarstvennyy univer-sitet (TGU). – EDN WGEPZU.
24. Poluchenie nanorazmernyh poroshkov oksida vol'fra-ma i vol'frama/ H.A Abdullin, A.A. Azatkaliev, M.T. Gab-dullin [i dr.] // Fizika tverdogo tela. – 2019. – T. 16, № 1. – S.163 – 168.
25. Poluchenie nanorazmernyh i ul'tradispersnyh po-roshkov metallov i ih karbidov elektrohimicheskim spo-sobom / A. V. Varaksin, V. A. Kostylev, V. L. Lisin [i dr.] // Butlerovskie soobscheniya. – 2014. – T. 37, № 1. – S. 76-83. – EDN SBMZNZ.
26. Poluchenie nanoporoshkov vol'frama metodom elek-tricheskogo vzryva provodnikov / A. P. Il'in, O. B. Naza-renko, D. V. Tihonov, G. V. Yablunovskiy // Izvestiya Tomsko-go politehnicheskogo universiteta. – 2005. – T. 308, № 4. – S. 68-70. – EDN HRTWJZ.
27. Patent № 2414992 C2 Rossiyskaya Federaciya, MPK B22F 9/00, B82B 3/00, C01B 31/34. Sposob polucheniya nanoporoshka karbida vol'frama : № 2009101478/02 : zayavl. 19.01.2009 : opubl. 27.03.2011 / V. A. Arhipov, A. B. Vorozhcov, S. A. Vorozhcov [i dr.] ; zayavitel' Gosudar-stvennoe obrazovatel'noe uchrezhdenie vysshego professi-onal'nogo obrazovaniya Tomskiy gosudarstvennyy univer-sitet (TGU). – EDN WGEPZU.
28. Patent № 2763814 C1 Rossiyskaya Federaciya, MPK B22F 9/20, B82B 3/00, C22B 7/00. Sposob polucheniya nano-dispersnyh poroshkov : № 2021102205 : zayavl. 29.01.2021 : opubl. 11.01.2022 / S. R. Vishnyakov, V. M. Gavrish, S. S. Vinogradskiy, R. I. Hikmatulloev. – EDN CEYCSI.
29. Uluchshenie mehanicheskih harakteristik kompozitov na osnove aramidnoy tkani za schet ispol'zovaniya vysokodis-persnyh vol'framsoderzhaschih poroshkov / V. M. Gavrish, Yu. O. Shagova, N. V. Sabirov, E. F. Harchenko // Redkie me-tally i materialy na ih osnove: tehnologii, svoystva i primenenie (REDMET-2024) : Sbornik tezisov 3-ey Mezh-dunarodnoy nauchno-prakticheskoy konferencii, posvya-schennoy pamyati akademika N.P. Sazhina, Moskva, 03–05 ap-relya 2024 goda. – Moskva: OOO Nauchnye tehnologii, 2024. – S. 135-136. – EDN FBNIRC.
30. Gavrish, V. M. Sravnenie stoykosti k istiraniyu stek-loplastikov na osnove razlichnyh matric, modificiro-vannyh aglomeratami nanodispersnogo poroshka karbida vol'frama WC / V. M. Gavrish, T. V. Chayka, A. Yu. Oleynik // Perspektivnye tehnologii i materialy : Materialy Mezhdunarodnoy nauchno-prakticheskoy konferencii, Seva-stopol', 06–08 oktyabrya 2021 goda. – Sevastopol': Fede-ral'noe gosudarstvennoe avtonomnoe obrazovatel'noe uchrezhdenie vysshego obrazovaniya "Sevastopol'skiy gosu-darstvennyy universitet", 2021. – S. 196-198. – EDN HAQZZR
31. Patent № 2782759 C1 Rossiyskaya Federaciya, MPK G21F 1/10. Kompozicionnyy material dlya zaschity ot kos-micheskoy radiacii i sposob ego polucheniya : № 2022108655 : zayavl. 31.03.2022 : opubl. 02.11.2022 / V. I. Pavlenko, Yu. R. Kolobov, V. M. Gavrish [i dr.] ; zayavitel' federal'noe gosudarstvennoe byudzhetnoe obrazovatel'noe uchrezhdenie vysshego obrazovaniya "Belgorodskiy gosudar-stvennyy tehnologicheskiy universitet im. V.G. Shuhova". – EDN PCAHBO.
