The impact of additive manufacturing and aerospace market growth on the titanium market
https://doi.org/10.26425/2658-3445-2026-9-1-102-118
Abstract
The impact of changes in the dynamics of the markets of additive technologies (3D printing) and the aerospace industry on the growth of the titanium market and its alloys has been studied, considering the scenario approach in conditions of economic instability. The data for 10 years of global demand for titanium and its alloys have been analyzed. Possible applications of titanium alloys in various industries have been considered. The analysis of the industry’s impact on achieving sustainable development goals in the context of stricter environmental regulations has been carried out. A step-by-step modeling plan has been presented for estimating the growth rate of the titanium market depending on the aerospace and additive technologies industries development.
Using a scenario approach, the dynamics of key consumer industries of titanium and its alloys has been analyzed, and the demand for the metal for each scenario has been calculated. The study results have shown that by 2050, the accelerated implementation of additive technologies and the growth of the aerospace sector will have a significant impact on the titanium market, while traditional sectors (chemical industry, energy) will maintain stable demand.
The increased use of titanium creates opportunities for exporting countries, including Russia, to increase supplies and develop deep processing of raw materials. The prerequisites for further development of the proposed toolkit using alternative and sophisticated models to assess the growth rate of the titanium market have been given.
About the Author
V. V. DegtyarevaRussian Federation
Viktoria V. Degtyareva, Cand. Sci. (Econ.), Assoc. Prof. at the Innovation Management Department
Moscow
References
1. Alfimov, V. I., Korolev, K. V. (2022). Prospects for Using Additive Technologies in the Creation of Aircraft Engine Components. Innovations. Science. Education, 52, 350–358. (In Russian).
2. Bashmakov, I. A. (2022). The Scale of Efforts Required to Decarbonize the Global Industry. Fundamental and Applied Climatology, 8(2), 151–174. (In Russian). https://doi.org/10.21513/2410-8758-2022-2-151-174
3. Gunter, V. E., Khodorenko, V. N. (2022). Development of biocompatible superelastic materials and implants with shape memory based on titanium nickelide for the creation of highly effective medical technologies. Issues of reconstructive and plastic surgery, 25-2(81), 45–56. (In Russian). https://doi.org/10.52581/1814-1471/81/05
4. Dmitriev, M. E. (2022). Greenhouse gas emission scenarios for Russia. Journal of the New Economic Association, 4(56), 201–206. (In Russian). https://doi.org/10.31737/2221-2264-2022-56-4-10
5. Dunenkova, E. N., Onishchenko, S. I., Kamchatova E. Yu., Grishin, V. N., Gureev, P. M., Dzyurdzya, O. A., et al. (2025). Managing sustainable development in the context of technological sovereignty. Moscow: Rusains. (In Russian)
6. Zherdeva, A. A. (2024). New materials and designs in additive manufacturing. Bulletin of the Voronezh Institute of High Technologies, 4(51). (In Russian).
7. Kyarimov, R. R., Shaposhnikov, N. N., & Mitryanin, A. V. (2022). Feasibility Study for the Application of Selective Laser Melting Additive Technology on the Example of Titanium Spacecraft Elements. Space Engineering and Technology, 4(39), 5–21. (In Russian).
8. Mashkovtsev, G. A., Bykhovskiy, L. Z., Remizova, L. I., & Chebotareva, O. S. (2016). On Providing the Russian Industry with Titanium Raw Materials. Mineral Resources of Russia. Economy and Management, 5, 9–15. (In Russian).
9. Maryushin, L. A., Sennikova, O. B., Mikirtychev, S. A., & Shvedov, I. D. (2023). Analysis of Temperature Dependencies of Titanium- and Nickel-Based Alloys. Energy Saving and Water Treatment, 1(141), 41–44. (In Russian).
10. Mozhegorova, Yu. V., Ilyinykh, G. V., & Korotaev, V. N. (2024). Carbon Footprint Assessment for the Production of Structural Materials Used in Hydrogen Energy. Ecology and Industry of Russia, 28(11), 33–39. (In Russian). https://doi.org/10.18412/1816-0395-2024-11-33-39
11. Tleshev, M. B., Kulmanbetov, R. I., Nysanova, B. Z., & Altynbekov, K. D. (2024). Features of the anti-corrosion properties of titanium implants with nanostructured coatings. Phthisiopulmonology, 3, 76–85. (In Russian). https://doi.org/10.26212/2227-1937.2024.24.74.011
12. Petrova, L. G., Lysak, V. V., & Malkova, E. V. (2022). Assessment of the titanium market in the current geopolitical situation. Problems of Expertise in the Automobile and Road Industry, 4(5), 18–30. (In Russian).
13. Polkin, I. S. (2015). Additive technologies of titanium alloys. Light alloy technology, 3. (In Russian).
14. Rozhkova, E. A., Kustov, A. V. (2023). Analysis of additive technologies in mechanical engineering and in the development of rocket and space systems. Mechanics of the XXI century, 22, 113–117. (In Russian).
15. Serikov, S. V. (2023). Evaluation of the fatigue limit of metals. Steel, 8, 46–49. (In Russian).
16. Sokolov, A. V. (2020). Modeling trends in the titanium metal market. World of Economics and Management, 20(4), 152–175. https://doi.org/10.25205/2542-0429-2020-20-4-152-175
17. Tokarev, S. P. (2024). Study of the economic benefits and challenges of implementing additive technologies in modern production. Nature Management Issues, 3(1), 64–73. (In Russian). https://doi.org/10.25726/q9989-0503-4013-n
18. Chirkunova, N. V., Islavath, N., & Dorogov, M. V. (2023). Titanium Dioxide for Hydrogen Economy: a Brief Review. Reviews on Advanced Materials and Technologies, 5(2), 56–76. https://doi.org/10.17586/2687-0568-2023-5-2-56-76
Review
For citations:
Degtyareva V.V. The impact of additive manufacturing and aerospace market growth on the titanium market. E-Management. 2026;9(1):102-118. (In Russ.) https://doi.org/10.26425/2658-3445-2026-9-1-102-118
JATS XML


























