I am a Leading Researcher (Dr.-Ing.) at M.N. Mikheev Institute of Metal Physics, Ural Branch of the Russian Academy of Sciences (IPM UB RAS, Russia). My current research endeavors encompass a broad spectrum of topics, encompassing both traditional and cutting-edge materials processing techniques. I investigate the potential of additive manufacturing, specifically laser cladding, to create functional materials with tailored performance, analyzing the synergistic effects of different material combinations and processing parameters to achieve enhanced wear resistance, mechanical strength, and high-temperature stability in metal matrix composite (MMC) coatings. Furthermore, I am actively exploring the potential of liquid metal dealloying as a novel and efficient technique for synthesizing porous titanium-based materials with controlled microarchitectures and enhanced biocompatibility for applications like implants, scaffolds for tissue regeneration, and drug delivery systems. My research focuses on investigating the use of medium- and high-entropy alloys (M-HEAs) in this process, recognizing their potential to offer improved mechanical properties and corrosion resistance compared to conventional titanium alloys. By combining these diverse research areas, I aim to contribute to the advancement of innovative materials with superior performance and functional capabilities for a variety of technological and societal challenges.
I am a Junior Researcher (PhD student) at M.N. Mikheev Institute of Metal Physics, Ural Branch of the Russian Academy of Sciences (IPM UB RAS, Russia). My research focuses on developing novel materials for various industrial applications, merging materials science with advanced manufacturing techniques. I investigate laser cladding to create metal matrix composite (MMC) coatings with tailored properties, aiming to develop coatings with enhanced wear resistance, mechanical strength, and high-temperature stability for applications in aerospace, energy, and biomedical engineering. Furthermore, I explore the potential of liquid metal dealloying to create porous titanium-based materials with controlled microarchitectures and enhanced biocompatibility for applications like implants, scaffolds for tissue regeneration, and drug delivery systems. My research utilizes medium- and high-entropy alloys (M-HEAs) in this process, recognizing their potential to offer improved mechanical properties and corrosion resistance compared to conventional titanium alloys. By combining these research areas, I aim to contribute to the development of advanced materials with superior functionalities and performance for specific applications.
