Peter Petrov | Materials Science | Best Researcher Award

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Dr. Peter Petrov | Materials Science | Best Researcher Award 

Principal Scientist, at Imperial College London, United Kingdom.

Dr. Peter K. Petrov is a Principal Research Scientist at the Department of Materials, Imperial College London, and serves as the Royce Technology Platform Lead for Diverse Thin Film Device Materials at the Henry Royce Institute. As the director of the Thin Film Device Manufacture facility, he provides leading UK universities and industrial partners with advanced resources for nano-scale thin film deposition, device patterning, and electrical characterization. Internationally recognized for his research into functional oxide thin films and microwave tunable devices, Dr. Petrov leads several EPSRC and EU-sponsored projects. His recent collaborations have resulted in significant advancements, including the development of thin Film Bulk Acoustic Resonators (FBARs) with electrically tunable resonance frequencies and methods to reverse pathological bone resorption in diabetic patients.

Professional Profile

Scopus

ORCID

Google Scholar​

Education 🎓

Dr. Petrov earned his Master of Science in Physics and Engineering and his Ph.D. in Technical Sciences from St. Petersburg State Electrotechnical University (LETI) in Russia. Further honing his expertise, he underwent training at Chalmers University of Technology in Gothenburg, Sweden. In February 2007, he joined the Department of Materials at Imperial College London, marking the beginning of his longstanding association with the institution.

Experience 🏫

With a career spanning over two decades, Dr. Petrov has made substantial contributions to the field of materials science. At Imperial College London, he leads a research group comprising postdoctoral research associates and Ph.D. students. Together, they have pioneered developments such as the first-ever thin Film Bulk Acoustic Resonators (FBARs) with electrically tunable resonance frequencies and CMOS-compatible alternative plasmonic thin films. His collaborations extend globally, working alongside researchers from leading universities and industrial partners like Ericsson AB and Murata Manufacturing Co.

Research Interests 🔬

Dr. Petrov’s research focuses on functional oxide thin films, microwave tunable devices, and the development of nano-scale thin films and structures for solar energy harvesting and active plasmonic devices. His interests also encompass the fabrication of nano enclosures for stable vaccine formulations and the development of methods for nanolithography and device fabrication for energy harvesting and biosensing. His interdisciplinary approach bridges materials science, physics, and engineering to address complex challenges.

Awards 🏆

In 2024, Dr. Petrov was honored with the prestigious Henry Royce Institute Award for Innovation by a Technical Professional. This accolade recognizes the significant impact that technical professionals have in advancing technology and deepening our understanding of the material world. Administered by the Institute of Materials, Minerals and Mining (IOM3) on behalf of the Henry Royce Institute, the award underscores Dr. Petrov’s influential contributions to the field.

Top Noted Publications 📚

  • “Experimental Observation of Negative Capacitance in Ferroelectrics at Room Temperature”

  • “The Rectenna Device: From Theory to Practice (A Review)”

  • “Quantifying Figures of Merit for Localized Surface Plasmon Resonance Applications: A Materials Survey”

  • “Titanium Oxynitride Thin Films with Tunable Double Epsilon-Near-Zero Behavior for Nanophotonic Applications”

  • “Optimised Pulsed Laser Deposition of ZnO Thin Films on Transparent Conducting Substrates”

Conclusion

Dr. Peter K. Petrov is a highly suitable candidate for a Best Researcher Award due to his outstanding contributions to materials science, thin-film technology, and biomedical applications. His leadership in both academic and industrial collaborations, coupled with his prestigious recognitions and impactful research, makes him a strong contender.

Theany To | Materials Science | Best Researcher Award

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Dr. Theany To | Materials Science | Best Researcher Award 

Postdoc fellow, at Univ Rennes, CNRS, IPR (Institut de Physique de Rennes) – UMR 6251, F-35000 Rennes, France.

Theany To is a dedicated researcher in glass mechanics, currently serving as a Marie-Curie Bienvenüe Post-doc at the Institute of Physics of Rennes (IPR), France (2023–2025). With a strong background in mechanical properties of glass, fracture toughness, and composite materials, Theany has made significant contributions to the field of materials science. He has collaborated with leading international researchers and industry partners, investigating the behavior of oxide glasses, silicate glasses, and novel glass-ceramic composites. Apart from research, he actively mentors students and participates in outreach activities, fostering scientific curiosity. Fluent in English, French, Danish, and Khmer, he enjoys engaging in football, volleyball, and scientific vulgarization. His enthusiasm for investigation and cooperation drives his passion for advancing the understanding of glass materials. 🏆🔬

Professional Profile

Scopus

ORCID

Google Scholar

Education 🎓

  • Ph.D. in Physics (Glass Mechanics), University of Rennes 1, France (2015–2019)
    Thesis: “Mechanical properties of innovated glasses and composite glasses – Cracking, Fracture Toughness, and Strength”

    • Developed insights into glass fracture mechanisms and composite structures.

    • Won a regional public award in a science communication contest.

  • Master’s Degree in Mechanical and Engineering Sciences, INSA Rennes, France (2014–2015)

    • Ranked 2nd out of 38 students in theory and 3rd in applications.

    • Specialized in material behavior under stress and fracture mechanics.

  • Bachelor’s Degree in Civil Engineering, Institute of Technology of Cambodia (2009–2014)

    • Focused on structural mechanics and tunnel construction.

    • Conducted research on cut-and-cover tunnel design.

Experience 🏢🔬

  • Marie-Curie Bienvenüe Post-doc, IPR, France (2023–2025)

    • Investigating mechanical properties of advanced glasses.

    • Supervising graduate students and collaborating on international projects.

  • Postdoctoral Researcher, IPGP, France (2022)

    • Explored mixed alkaline silicate glasses and mechanical behavior.

    • Published multiple high-impact journal articles.

  • Researcher, Aalborg University, Denmark (2019–2022)

    • Supervised 4 Master’s and multiple Ph.D. students.

    • Led projects on oxide glasses, crack-resistant materials, and phase separation.

  • Lecturer, University of Rennes 1, France (2017–2018)

    • Taught Mechanical Behavior of Materials to Master’s students.

    • Conducted practical solid mechanics courses for undergraduates.

Research Interests 🔍

  • Glass Fracture and Toughness: Investigating how glasses break under stress and methods to enhance durability.

  • Oxide Glasses & Composites: Exploring materials like lithium aluminoborate, galliumborate, and phosphosilicate glasses.

  • High-Pressure Glass Mechanics: Studying how glass properties change under extreme conditions.

  • Industrial Glass Applications: Collaborating with companies to develop stronger, more resilient glass materials.

  • Experimental and Theoretical Modeling: Combining experimental methods with computational simulations for advanced material analysis.

Awards & Honors 🏆

  • Regional Public & Internet Award (2017) – 🏅 “My Thesis in 3 Minutes” (French Science Communication Contest).

  • Marie-Curie Bienvenüe Postdoctoral Fellowship (2023–2025) – 🌍 Prestigious European postdoctoral research grant.

  • 2nd Place in Master’s Program (2015) – 🎓 Ranked among top students at INSA Rennes.

  • Multiple Research Grants & Collaboration Awards – 📜 Recognition for contributions to international glass mechanics research.

Top Noted Publications 📚🔗

Below are some of Theany To’s notable publications with links to full texts:

  • “Thermal and mechanical properties of Mg–Al–Si–O–N glasses with up to 6.2 at.% nitrogen”
    Authors: Theany To, et al.
    Journal: Journal of the American Ceramic Society, 2025.
    Summary: This study investigates the thermal and mechanical properties of magnesium-aluminum-silicon oxynitride (Mg–Al–Si–O–N) glasses containing up to 6.2 atomic percent nitrogen. The research aims to understand how nitrogen incorporation influences the structure and properties of these glasses. While the specific details of this study are not available in the provided sources, related research has shown that increasing aluminum content in similar glass systems leads to higher glass transition and crystallization temperatures, as well as increased viscosity. These changes are attributed to the progressive polymerization of the silicate network due to the glass-forming role of Al₂O₃.mostwiedzy.pl+1KFUPM+1KFUPM+1mostwiedzy.pl+1

  • “Fracture behavior of brittle particulate composites”
    Authors: T. Lacondemine, Theany To, et al.
    Journal: Materialia, 2024.
    Summary: This paper examines the fracture behavior of brittle matrix composites containing particulate reinforcements. Although specific details are not available, earlier studies have explored similar systems. For instance, research on glass matrices with nickel spheres investigated how the inclusion of metal particles affects fracture energy and crack propagation. The findings indicated that the presence of these particles can lead to local crack blunting, thereby increasing the material’s fracture energy.SpringerLinkSpringerLinkSpringerLink

  • “Mechanical and Electrochemical Properties of Lithium Aluminoborate Glasses”
    Authors: Theany To, et al.
    Journal: Glass Europe, 2024.
    Summary: This research focuses on lithium aluminoborate glasses, analyzing their mechanical strength and electrochemical behavior. The study aims to elucidate the relationship between the glass composition and its performance in applications such as solid-state batteries.

  • “Crystallization and mechanical properties of a barium titanosilicate glass”
    Authors: P. Mezeix, Theany To, et al.
    Journal: Journal of Materials Science, 2024.
    Summary: This paper investigates the crystallization behavior and mechanical properties of barium titanosilicate glass. The research explores how controlled crystallization impacts the material’s hardness and fracture toughness, providing insights into the development of glass-ceramic materials with tailored properties.

  • “Comparing the effects of Ga₂O₃ and Al₂O₃ on sodium borate glasses”
    Authors: Theany To, et al.
    Journal: Journal of Non-Crystalline Solids, 2023.
    Summary: This study compares the influence of gallium oxide (Ga₂O₃) and aluminum oxide (Al₂O₃) additives on the structure and properties of sodium borate glasses. The research aims to determine how these oxides affect factors such as thermal stability, hardness, and chemical durability, contributing to the understanding of modifier effects in glass science.

Conclusion

Theany To is a highly accomplished researcher with outstanding contributions to glass mechanics, extensive academic mentorship, and a strong collaborative network. With further engagement in grant leadership and industrial applications, they would be an excellent candidate for a Best Researcher Award.