Hyesung Park | Chemistry and Materials Science | Best Researcher Award

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Prof. Dr. Hyesung Park | Chemistry and Materials Science | Best Researcher Award

Korea University | South Korea

Dr. Hyesung Park, a distinguished Professor at Korea University, is an internationally recognized authority in hetero-dimensional materials synthesis and their applications in functional devices, including energy harvesting, nanoelectronics, and nanophotonics. His academic journey spans world-leading institutions such as MIT, Northwestern University, and UNIST, where he has consistently advanced renewable energy technologies and next-generation device engineering. He earned his Ph.D. in Electrical Engineering and Computer Science from MIT with groundbreaking research on CVD graphene for organic photovoltaics, pioneering innovations in transparent conducting electrodes that have shaped subsequent advances in the field. Before joining Korea University, he held prestigious research and faculty positions that further strengthened his international reputation. At Korea University, Dr. Park leads pioneering work in integrative energy engineering, with research spanning hybrid nanostructures, scalable perovskite solar cells, electro/photo-catalysis, graphene-based devices, and triboelectric nanogenerators, producing notable innovations in solar cell production and energy harvesting materials. He has authored 116 Publications, accumulated 5,452 citations, and holds an impressive h-index of 36, reflecting the global impact of his scholarship. His highly cited works on graphene electrodes and hybrid solar cells have been published in top-tier journals such as Nature Nanotechnology, ACS Nano, and Advanced Energy Materials. Widely acclaimed for his leadership, impactful publications, and international collaborations, Dr. Hyesung Park is celebrated not only for advancing materials science and energy technologies but also for inspiring future scientists and engineers through his mentorship and academic contributions. Honored with national and international recognition, he exemplifies excellence in research, education, and innovation, and his pioneering contributions continue to drive breakthroughs in sustainable energy technologies that are shaping a cleaner and more efficient future.

Profile: Scopus | Google Scholar | ORCID

Featured Publications

Kim, K. K., Reina, A., Shi, Y., Park, H., Li, L. J., Lee, Y. H., & Kong, J. (2010). Enhancing the conductivity of transparent graphene films via doping. Nanotechnology, 21(28), 285205.

Park, H., Brown, P. R., Bulović, V., & Kong, J. (2012). Graphene as transparent conducting electrodes in organic photovoltaics: Studies in graphene morphology, hole transporting layers, and counter electrodes. Nano Letters, 12(1), 133–140.

Park, H., Rowehl, J. A., Kim, K. K., Bulović, V., & Kong, J. (2010). Doped graphene electrodes for organic solar cells. Nanotechnology, 21(50), 505204.

Park, H., Chang, S., Zhou, X., Kong, J., Palacios, T., & Gradečak, S. (2014). Flexible graphene electrode-based organic photovoltaics with record-high efficiency. Nano Letters, 14(9), 5148–5154.

Park, H., Chang, S., Jean, J., Cheng, J. J., Araujo, P. T., Wang, M., Bawendi, M. G., & Kong, J. (2013). Graphene cathode-based ZnO nanowire hybrid solar cells. Nano Letters, 13(1), 233–239.

Koo, D., Jung, S., Seo, J., Jeong, G., Choi, Y., Lee, J., Lee, S. M., Cho, Y., Jeong, M., & Park, H. (2020). Flexible organic solar cells over 15% efficiency with polyimide-integrated graphene electrodes. Joule, 4(5), 1021–1034.

Oh, N. K., Seo, J., Lee, S., Kim, H. J., Kim, U., Lee, J., Han, Y. K., & Park, H. (2021). Highly efficient and robust noble-metal free bifunctional water electrolysis catalyst achieved via complementary charge transfer. Nature Communications, 12(1), 4606.

Oh, N. K., Kim, C., Lee, J., Kwon, O., Choi, Y., Jung, G. Y., Lim, H. Y., Kwak, S. K., Kim, G., & Park, H. (2019). In-situ local phase-transitioned MoSe2 in La0.5Sr0.5CoO3-δ heterostructure and stable overall water electrolysis over 1000 hours. Nature Communications, 10(1), 1723.

Neetu Yadav | Materials Science | Best Researcher Award

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Ms. Neetu Yadav | Materials Science | Best Researcher Award

Department of Physics, University of Lucknow | India

Neetu Yadav is a passionate and dedicated researcher specializing in Material Science, with a keen interest in humidity and gas sensors. Born on April 18, 1996, in India, she currently resides in Pantnagar, Uttarakhand. Her academic journey, combined with a growing list of publications, reflects her commitment to advancing sensor technology through nanomaterials and transition metal oxides. With excellent research, communication, and analytical skills, Neetu brings a multidisciplinary approach to scientific inquiry, bridging physics, chemistry, and materials engineering.

Professional profile👤

Scopus

Google Scholar

ORCID

Strengths for the Awards✨

Ms. Neetu Yadav exemplifies the profile of an emerging researcher in the domain of material science and sensor technology. Her ongoing Ph.D. research at the University of Lucknow focuses on transition metal oxides for gas and humidity sensing applications, a field of significant relevance to environmental monitoring and industrial safety. Despite being at an early stage of her career, she has already co-authored 10+ peer-reviewed publications in reputable journals such as Applied Surface Science, International Journal of Hydrogen Energy, and Physica E, with multiple articles indexed in Scopus and cited internationally.

Her collaborative projects and contributions to interdisciplinary studies involving nanostructures, thin films, irradiation effects, and sensor fabrication underscore her technical competence. She has also co-authored book chapters published by Springer and other academic platforms, indicating her global academic reach. Moreover, her participation in national and international conferences, workshops, and symposiums, as well as involvement in outreach activities like essay competitions and inter-university sports, highlights her holistic development.

🎓 Education

Neetu Yadav is presently pursuing her Ph.D. in Material Science from the Department of Physics, University of Lucknow, focusing on the synthesis and characterization of transition metal oxides for sensor applications. She completed her Master’s in Physics (2019) from the same university with a second division. Prior to that, she earned her B.Sc. in Physics, Chemistry, and Mathematics (2017) from Kumaun University, securing a first division. She also completed her Intermediate and High School from Rajeev Gandhi Navodaya Vidhyalaya, both with top ranks.

🧪 Experience

Neetu has developed hands-on experience through intensive lab work, workshops, and conferences. Her current research explores optical and structural properties of advanced materials, focusing on their applications in gas and humidity sensing. She has actively participated in experimental setups involving thin-film deposition, surface modification via ion irradiation, and nanomaterial synthesis — enriching her technical proficiency and collaborative skills.

🔍 Research Interests On Materials Science

Her research interests center around the synthesis and structural characterization of transition metal oxides, sensor device fabrication, thin films, and ion beam irradiation effects. She aims to enhance sensor performance for environmental monitoring by manipulating nano-scale properties of oxides like MoO₃, WO₃, SnO₂, and CuO. Her interdisciplinary curiosity also extends into nanotechnology’s societal and ethical dimensions. 📊

🏆 Awards & Recognition

Neetu received an Honorable Mention in the All India Essay Writing Event (2016), organized by Shri Ram Chandra Mission & the UN Information Centre. She has also earned accolades in district-level and inter-parliamentary volleyball tournaments. Her involvement in academic events and diverse interests from chess to painting reflect a well-rounded personality.

📚 Publications

Below are selected publications showcasing Neetu Yadav’s contributions to materials science and sensor technology:

  1. Gamma irradiation induced surface modification of V₂O₅ thin films, Applied Surface Science, 2025 — cited by researchers for its relevance to sensor enhancement mechanisms.

  2. Analysis of nanostructured Bi₂O₃-doped MoO₃, Materials Today: Proceedings, 2024 — contributed to optical and humidity sensor evaluation.

  3. Room temperature LPG sensing of Ag-doped CuO:SnO₂, Physica E, 2024 — investigated gas sensing efficiency.

  4. Effects of 100 MeV Ni⁷⁺ ion irradiation on MoO₃ thin films, Nuclear Instruments and Methods B, Oct 2024.

  5. Enhanced hydrogen gas sensing with Ag-doped WO₃, International Journal of Hydrogen Energy, 2023.

  6. SnO₂@ZnO based chemiresistor for Ammonia sensing, Materials Chemistry and Physics, Dec 2023.

  7. Yttrium-Cerium oxide sensor for H₂ detection, Engineering Proceedings, 2023.

  8. NiO and SnO₂ nanoparticles for humidity sensing, Interactions, 2022.

  9. XRD studies of sol-gel derived SnO₂, Int. Conf. on Materials Processing & Applications, 2023.

  10. 120MeV Ni⁷⁺ irradiation effects on WO₃, Journal of Alloys and Compounds, 2025.

📘 Book Chapters:

  • Influence of Temperature on Humidity Sensor (2023), in IIP Series Vol. 3.

  • Nanotechnology: Social Acceptance & Privacy (2024), Springer.

  • Role of Nanotechnology in Sensor Fabrication (2023), IIP Series Vol. 3.

🧠 Conclusion

Neetu Yadav stands out as a promising researcher whose work embodies academic rigor, technical innovation, and societal relevance. Her deep focus on material-based sensors and her contributions through high-impact publications and active participation in global scientific discussions make her an outstanding candidate for the “Best Researcher Award” in Forensic Scientist Awards. 🌟 Her fusion of scientific creativity, hands-on experimentation, and cross-disciplinary collaboration demonstrates not only academic excellence but a steadfast commitment to real-world impact.