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The PhD project focuses on the development of novel ultrathin antifriction coatings based on polysilazane (PSZ) and graphene-containing nanocomposite materials. The research aims to reduce friction, wear, and energy losses in mechanical systems through advanced surface engineering solutions. The developed coatings will be evaluated for applications in bearings and other engineering components operating under demanding conditions.
Ultrathin antifriction coatings based on polysilazane matrices reinforced with nano-carbon materials such as graphene represent a rapidly developing class of surface-engineering technologies aimed at reducing wear, friction, and energy losses in mechanical systems. Polysilazanes provide excellent chemical stability, high-temperature resistance, and the ability to form dense Si-O/Si-N ceramic-like networks upon curing. When combined with graphene or graphene-like nanosheets, the resulting hybrid films exhibit enhanced mechanical strength, lubricity, and resistance to tribo-chemical degradation. The reduction of friction and wear is one of the key challenges in modern engineering, as tribological losses account for a significant share of global energy consumption and maintenance costs. Advanced antifriction coatings offer a promising route for improving the efficiency, reliability, and service life of mechanical components operating under demanding conditions. Bearings, sliding contacts, and other tribological systems can particularly benefit from thin protective coatings capable of reducing friction while maintaining mechanical and chemical stability. The aim of this PhD project is to develop and investigate ultrathin polysilazane/graphene hybrid coatings prepared by dip-coating and electrophoretic deposition techniques. The research will focus on understanding the relationships between coating composition, processing parameters, microstructure, and tribological performance. Special attention will be paid to coating adhesion, wear resistance, friction behaviour, durability, and resistance to environmental degradation. The developed coatings will be characterized using advanced analytical methods to evaluate their morphology, chemical composition, mechanical properties, and functional performance. Experimental results will be used to establish structure–property–performance relationships and to identify optimal coating architectures for engineering applications.
Main supervisor: Veroonika Shirokova: School of Engineering: Virumaa College: Applied Mechanics and Sustainable Energy Technology Research Group
Co-Supervisor: Sergei Bereznev: School of Engineering: Department of Materials and Environmental Technology: Laboratory of Photovoltaic Materials
Co-Supervisor: Elizaveta Shmagina: School of Engineering: Virumaa College: Applied Mechanics and Sustainable Energy Technology Research Group
Tallinn University of Technology (TalTech) is an international scientific community with approximately 9,000 students and 2,000 employees; it is one of the largest universities in Estonia, the leading EU country in digitalisation. The university's strengths are broad multidisciplinary study/research interests, a modern research environment, and strong collaboration with international educational and research institutions. TalTech is aiming to be an organisation leading the way to a sustainable digital future.
The Mechanical Engineering and Energy Technology Processes Control Work Group at Tallinn University of Technology, Virumaa College conducts research in mechanical engineering, materials technology, industrial process optimization, and sustainable energy systems.
Research activities include advanced materials and surface engineering, functional and antifriction coatings, tribology and wear mechanisms, condition monitoring and reliability of mechanical systems, sustainable energy technologies, industrial energy efficiency, and experimental characterization of materials and engineering components.
The work group collaborates with TalTech researchers and international partners, offering PhD students opportunities to participate in interdisciplinary research projects and contribute to innovative engineering solutions.
For information about the admission process, please visit the PhD Admission homepage or for questions relating to the process, please contact [email protected]
Tallinn University of Technology (TUT) is the only technological university in Estonia and the flagship of Estonian engineering and technical educa...
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