Yura Choi | Chemistry and Materials Science | Innovative Research Award

Innovative Research Award

Yura Choi
Soonchunhyang University, South Korea

Yura Choi
Affiliation Soonchunhyang University
Country South Korea
Scopus ID 57220855960
Documents 10
Citations 50
h-index 4
Subject Area Chemistry and Materials Science
Event International Forensic Scientist Awards
Google Scholar ID 1AgSdeEAAAAJ

Yura Choi is a researcher affiliated with Soonchunhyang University whose scholarly work focuses on chemistry and materials science, particularly advanced polymeric materials, photocurable resins, additive manufacturing, and functional nanomaterials. Through interdisciplinary collaborations, the researcher has contributed to investigations involving stereolithography, perovskite stabilization, biomaterials, and energy-related polymer systems. Publications indexed in Scopus demonstrate a growing research profile characterized by methodological development and practical applications in biomedical engineering and advanced manufacturing.[1]

Abstract

Yura Choi has established an emerging research profile centered on polymer chemistry, photocurable materials, and advanced manufacturing technologies. Published studies address the design of stereolithography resins, enhancement of mechanical properties for biomedical applications, stabilization of perovskite materials, and optimization of polymer systems for energy conversion. These investigations demonstrate integration of material synthesis with engineering applications while contributing to knowledge supporting sustainable and functional material development.[2]

Keywords

Polymer Chemistry, Materials Science, 3D Printing, Stereolithography, Photocurable Resin, Biomaterials, Nanomaterials, Perovskites, Solar Cells, Advanced Manufacturing.

Introduction

Modern materials research increasingly combines chemistry, engineering, and manufacturing technologies to create functional solutions for healthcare and industrial applications. Yura Choi’s publications reflect this multidisciplinary direction through studies emphasizing polymer formulation, mechanical performance, and scalable fabrication techniques. Collaborative research has contributed to improved understanding of photocurable materials and additive manufacturing systems while supporting innovation in biomedical and energy-related technologies.[3]

Research Profile

The research portfolio includes ten Scopus-indexed publications with fifty citations and an h-index of four. Principal research interests include polymer synthesis, photocurable materials, stereolithography, nanocomposites, biomaterials, and functional coatings. Published work demonstrates consistent participation in multidisciplinary collaborations involving chemistry, materials engineering, and biomedical device development.[1]

Research Contributions

  • Developed bisphenol-A-glycidyl-methacrylate and trimethylolpropane-triacrylate based stereolithography materials.
  • Investigated phase-transition strategies for improving lead halide perovskite stability.
  • Enhanced photocurable 3D printing materials using potassium titanate additives for craniofacial applications.
  • Contributed to polymer-based solar cell material development.
  • Studied swelling behavior of advanced acrylate-based photoresist polymers.

Publications

  • Polymers (2022): Development of stereolithography 3D printing materials.
  • Nanomaterials (2022): Stability improvement of ball-milled lead halide perovskites.
  • Biomimetics (2024): Mechanical strengthening of photocurable 3D printing materials.
  • Polymers (2021): Benzotriazole-based materials for inverted solar cells.
  • Materials (2024): Swelling behavior of acrylate-based photoresist polymers.

Research Impact

Research outputs demonstrate measurable academic visibility through peer-reviewed publications, citation performance, and interdisciplinary collaborations. The work supports technological progress in additive manufacturing, functional polymers, biomedical materials, and renewable energy applications. These contributions provide useful scientific evidence for future material optimization and practical engineering implementations.[4]

Award Suitability

Based on the available scholarly record, Yura Choi demonstrates research activity consistent with the objectives of the Innovative Research Award. Contributions to advanced polymer systems, photocurable materials, biomedical engineering applications, and materials innovation illustrate sustained scientific engagement and collaborative research productivity within chemistry and materials science.[5]

Conclusion

Yura Choi’s academic profile reflects continued contributions to materials science through research on polymers, additive manufacturing, nanomaterials, and biomedical applications. The documented publication record and collaborative research activities indicate an evolving scholarly career that contributes to both scientific understanding and practical technological advancement within modern materials research.

References

  1. Elsevier. (n.d.). Scopus author details: Yura Choi, Author ID 57220855960. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=57220855960
  2. Choi, Y., et al. (2022). Development of bisphenol-A-glycidyl-methacrylate-and trimethylolpropane-triacrylate-based stereolithography 3D printing materials. Polymers.
    https://doi.org/10.3390/polym14235198
  3. Kim, J., et al. (2022). Improving the stability of ball-milled lead halide perovskites. Nanomaterials.
    https://doi.org/10.3390/nano12060920
  4. Choi, Y., et al. (2024). Enhancing the mechanical strength of a photocurable 3D printing material. Biomimetics.
    https://doi.org/10.3390/biomimetics9110698
  5. Lee, C.J., et al. (2024). Swelling Behavior of Acrylate-Based Photoresist Polymers Containing Cycloaliphatic Groups of Various Sizes. Materials.
    https://doi.org/10.3390/ma17225465

Xingmei Guo | Chemistry and Materials Science | Research Excellence Award

Prof. Xingmei Guo | Chemistry and Materials Science | Research Excellence Award

Jiangsu University of Science and Technology | China

Prof. Xingmei Guo is an accomplished researcher in materials chemistry with expertise in electrochemical energy conversion, catalysis, and advanced functional materials. She has published 102 Scopus-indexed research articles, contributing significantly to the development of innovative energy materials. Her work has garnered 3,115 citations with an h-index of 32, reflecting strong academic impact. Her research includes multiple completed and ongoing projects, along with 10 patents demonstrating innovation in electrochemical technologies. She actively engages in collaborative research and serves on an editorial board, supporting scientific dissemination. Her contributions advance sustainable energy solutions through novel material design, electrochemical performance optimization, and applied research outcomes.

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View Scopus Profile  View ORCID Profile

Featured Publications

Alžběta Danielisová | Humanities and Science Integration | Excellence in Research Award

Dr. Alžběta Danielisová | Humanities and Science Integration | Excellence in Research Award

Institute of Archaeology of the CAS, Prague | Czech Republic

Dr. Alžběta Danielisová is a distinguished archaeological scientist whose research integrates geochemistry, biochemistry, and material science to advance the understanding of past human societies across Europe and Southern Arabia. Her work focuses on the systematic interpretation of biochemical and geochemical datasets, combining humanities-driven archaeological inquiry with innovative scientific methodologies. She specializes in multi-isotopic, proteomic, and provenance analyses applied to metallic artefacts particularly copper alloys as well as biological materials, including human and animal remains, enabling high-resolution reconstructions of ancient mobility, dietary habits, technological practices, and socio-economic organization. Dr. Alžběta Danielisová has an extensive publication record, with 35 Scopus-indexed articles, 514 citations from 452 citing documents, and an h-index of 11, reflecting her significant impact in the field of archaeological science. Her research has produced major insights into Iron Age transformations in Central Europe, early Medieval cosmopolitanism in Finland, Neolithic occupation in Oman, and environmental adaptation in marginal landscapes. In collaboration with the Max Planck Institute in Mainz, she has pioneered nitrogen isotope analysis of human enamel, providing novel perspectives on dietary resilience and life-history trajectories. Her completed and ongoing projects expand archaeological science through the integration of isotopic systems, advanced geochemical modelling, and spatial data analysis, contributing to an understanding of risk management, resource strategies, and long-term cultural resilience. Recognized internationally for her interdisciplinary innovation, methodological advancements, and collaborative research, Danielisová continues to shape the field by producing evidence-based reconstructions of ancient lifeways, offering both historical insight and frameworks that inform contemporary studies of sustainability, adaptation, and socio-environmental dynamics.

Profiles: Scopus | ORCID | ResearchGate

Featured Publications

  1. Danielisová, A., Hajnalova, M., Pokorna, A., Kočár, P., Kertés, S., Bursák, D., Pachnerova Brabcova, K., Tvrdý, Z., Šálková, T., Komárková, V., & Světlík, I. (2025). Multiproxy evidence of millet reliance and selective dietary change during Iron Age transformation in Central Europe. Scientific Reports, 15(1).

  2. Danielisová, A., Maiorano, M. P., Sneberger, J., Ackerman, L., Daněček, D., Garba, R., Martínez-García, A., & Lüdecke, T. (2025). The first collective Neolithic megalithic tomb in Oman. Antiquity.

  3. Garba, R., Czech Academy of Sciences, & Danielisová, A. (2025). Archaeological landscape and environmental dynamics of Duqm and Nejd (ARDUQ) | Season 2 (2022–2023). In Athar: Bulletin of Archaeological Research in the Sultanate of Oman, Issue 1 (pp. 54–62). Ministry of Heritage and Tourism, Sultanate of Oman, Muscat.

  4. Nordfors, U., Danielisová, A., Etu‐Sihvola, H., Ackerman, L., Mannermaa, K., & Arppe, L. (2025). The origins of Viking Age dogs in Luistari, Eura, Finland. International Journal of Osteoarchaeology, 35(4).

  5. Danielisová, A., Nordfors, U., Kertés, S., Wessman, A., Ackerman, L., Oinonen, M., Etu-Sihvola, H., & Arppe, L. (2025). Multi-isotopic evidence reveals the emergence of a cosmopolitan community at the Luistari cemetery in Eura, Finland, during the early Medieval period (600–1130 CE). Archaeological and Anthropological Sciences, 17(3).