Ho Won Jang | Materials Science | Best Paper Award

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Prof. Dr. Ho Won Jang | Materials Science | Best Paper Award

Professor at Seoul National University, South Korea

Prof. Ho Won Jang is a distinguished professor in the Department of Materials Science and Engineering at Seoul National University (SNU), South Korea. With a career spanning over two decades, he has made groundbreaking contributions to materials science, particularly in electronic and electrochemical applications. His research focuses on advanced materials, including memristive materials, nanostructures, and epitaxial thin films, which have significant implications for nanoelectronics, neuromorphic computing, and sustainable energy solutions. As a globally recognized scientist, he has been actively involved in editorial boards, international collaborations, and high-impact research publications, shaping the future of electronic materials. His leadership roles in academia and professional societies highlight his commitment to advancing science and mentoring young researchers. With an extensive portfolio of research excellence and prestigious accolades, Prof. Jang continues to be a driving force in cutting-edge materials research, contributing significantly to the evolution of modern technologies.

Professional Profile

Education

Prof. Ho Won Jang earned his Ph.D. in Materials Science and Engineering from POSTECH (Pohang University of Science and Technology), Korea, in 2004, after completing his M.S. (2001) and B.S. (1999) degrees at the same institution. His academic journey was marked by a strong foundation in nanomaterials, thin films, and semiconductor physics, which paved the way for his pioneering research in advanced materials. During his Ph.D., he focused on the design and synthesis of functional materials for electronic applications, laying the groundwork for his future studies in epitaxial thin films and nanostructured devices. His early research contributions were recognized through multiple prestigious awards, demonstrating his academic excellence and innovative approach to materials science. His education at one of Korea’s leading engineering institutions provided him with the technical expertise and research capabilities that would later define his career as a top-tier scientist in the field.

Professional Experience

Prof. Jang began his professional career as a Postdoctoral Fellow at POSTECH (2004-2005) before moving to the University of Wisconsin-Madison (2006-2009) as a Research Associate. In 2006, he joined the Korea Institute of Science and Technology (KIST) as a Senior Research Scientist, where he led several high-impact projects in nanoelectronics and electrochemical applications. His transition to Seoul National University in 2012 as a Professor marked a significant milestone in his career, where he has since played a crucial role in advancing research in materials science and engineering. Over the years, he has served as an editor for multiple international journals, collaborated with leading global researchers, and contributed to key advancements in electronic materials. His leadership positions, including serving as Associate Dean at SNU’s College of Engineering (2021-2024), highlight his influence in shaping the future of materials research and education.

Research Interests

Prof. Jang’s research focuses on epitaxial thin films, memristive materials, electrochemical catalysts, and nanosensors for next-generation electronic and energy applications. His studies on Mott insulators, neuromorphic computing, and electronic nose/tongue technologies have led to innovative breakthroughs in artificial intelligence-driven materials and nanoelectronic devices. Additionally, his work on localized surface plasmon resonance sensors and micro-light-emitting diodes (µLEDs) has potential applications in biomedical sensing and next-generation displays. His research in electrodes and catalysts for water splitting and CO₂ reduction aligns with global efforts toward sustainable and renewable energy solutions. By integrating multidisciplinary approaches, including nanotechnology, chemistry, and physics, he continues to explore novel materials with enhanced functionalities for computing, sensing, and clean energy applications, making significant contributions to both fundamental science and industrial innovation.

Awards and Honors

Prof. Ho Won Jang has received numerous prestigious awards for his outstanding contributions to materials science and engineering. His accolades include the Top 2% Scientists ranking by Stanford University (2022), the ACS Nano Top Contributor in Korea (2024), and the Academic Research and Education Award from SNU (2023). He has also been recognized with the 2021 Science and Technology Excellence Paper Award of Korea and multiple Best Paper Awards from leading conferences and institutions. His early achievements include the Young Ceramist Award (2014) and Young Scholarship Award (2014), highlighting his contributions to ceramic materials research. Additionally, he has played a vital role as an editorial board member for major scientific journals and a reviewer for over 200 high-impact journals, further solidifying his reputation as a leading scientist in materials research. His numerous honors reflect his exceptional research impact, leadership, and dedication to advancing materials science.

Conclusion

Prof. Ho Won Jang is highly suitable for the Research Best Paper Award, given his exceptional research contributions, prestigious recognitions, and leadership in the field of materials science and engineering. His extensive publication record, awards, and editorial roles further validate his expertise. If the award criteria favor cutting-edge innovation and research influence, he would be an excellent candidate. Strengthening the application by highlighting real-world applications, interdisciplinary collaborations, and mentoring efforts could further solidify his case.

Publications Top Noted

  1. Tunneling electroresistance effect in ferroelectric tunnel junctions at the nanoscale

    • Authors: A. Gruverman, D. Wu, H. Lu, Y. Wang, H. W. Jang, C. M. Folkman, et al.
    • Year: 2009
    • Citations: 685

  2. Ferroelastic switching for nanoscale non-volatile magnetoelectric devices

    • Authors: S. H. Baek, H. W. Jang, C. M. Folkman, Y. L. Li, B. Winchester, J. X. Zhang, et al.
    • Year: 2010
    • Citations: 550

  3. Giant piezoelectricity on Si for hyperactive MEMS

    • Authors: S. H. Baek, J. Park, D. M. Kim, V. A. Aksyuk, R. R. Das, S. D. Bu, et al.
    • Year: 2011
    • Citations: 514

  4. One-dimensional oxide nanostructures as gas-sensing materials: review and issues

    • Authors: K. J. Choi, H. W. Jang
    • Year: 2010
    • Citations: 473

  5. Carbon and graphene quantum dots: a review on syntheses, characterization, biological and sensing applications for neurotransmitter determination

    • Authors: S. Tajik, Z. Dourandish, K. Zhang, H. Beitollahi, Q. V. Le, H. W. Jang, et al.
    • Year: 2020
    • Citations: 446

  6. Organolead halide perovskites for low operating voltage multilevel resistive switching

    • Authors: J. Choi, S. Park, J. Lee, K. Hong, D. H. Kim, C. W. Moon, et al.
    • Year: 2016
    • Citations: 361

  7. Domain engineering for enhanced ferroelectric properties of epitaxial (001) BiFeO thin films

    • Authors: H. W. Jang, D. Ortiz, S. H. Baek, C. M. Folkman, R. R. Das, P. Shafer, et al.
    • Year: 2009
    • Citations: 351

  8. Shape-controlled bismuth nanoflakes as highly selective catalysts for electrochemical carbon dioxide reduction to formate

    • Authors: S. Kim, W. J. Dong, S. Gim, W. Sohn, J. Y. Park, C. J. Yoo, H. W. Jang, J. L. Lee
    • Year: 2017
    • Citations: 334

  9. Ferroelectricity in strain-free thin films

    • Authors: H. W. Jang, A. Kumar, S. Denev, M. D. Biegalski, P. Maksymovych, C. W. Bark, et al.
    • Year: 2010
    • Citations: 334

  10. Self-activated transparent all-graphene gas sensor with endurance to humidity and mechanical bending

  • Authors: Y. H. Kim, S. J. Kim, Y. J. Kim, Y. S. Shim, S. Y. Kim, B. H. Hong, H. W. Jang
  • Year: 2015
  • Citations: 326
  1. Tailoring a two-dimensional electron gas at the LaAlO3/SrTiO3 (001) interface by epitaxial strain
  • Authors: C. W. Bark, D. A. Felker, Y. Wang, Y. Zhang, H. W. Jang, C. M. Folkman, et al.
  • Year: 2011
  • Citations: 312
  1. Strain-induced polarization rotation in epitaxial (001) thin films
  • Authors: H. W. Jang, S. H. Baek, D. Ortiz, C. M. Folkman, R. R. Das, Y. H. Chu, et al.
  • Year: 2008
  • Citations: 309
  1. Perspectives and challenges in multilayer ceramic capacitors for next-generation electronics
  • Authors: K. Hong, T. H. Lee, J. M. Suh, S. H. Yoon, H. W. Jang
  • Year: 2019
  • Citations: 307
  1. Organic–Inorganic hybrid halide perovskites for memories, transistors, and artificial synapses
  • Authors: J. Choi, J. S. Han, K. Hong, S. Y. Kim, H. W. Jang
  • Year: 2018
  • Citations: 303
  1. Metallic and insulating oxide interfaces controlled by electronic correlations
  • Authors: H. W. Jang, D. A. Felker, C. W. Bark, Y. Wang, M. K. Niranjan, C. T. Nelson, et al.
  • Year: 2011
  • Citations: 287
  1. Recent advances toward high-efficiency halide perovskite light-emitting diodes: review and perspective
  • Authors: Q. V. Le, H. W. Jang, S. Y. Kim
  • Year: 2018
  • Citations: 278
  1. Spin injection/detection using an organic-based magnetic semiconductor
  • Authors: J. W. Yoo, C. Y. Chen, H. W. Jang, C. W. Bark, V. N. Prigodin, C. B. Eom, A. J. Epstein
  • Year: 2010
  • Citations: 260
  1. Ultraselective and sensitive detection of xylene and toluene for monitoring indoor air pollution using Cr-doped NiO hierarchical nanostructures
  • Authors: H. J. Kim, J. W. Yoon, K. I. Choi, H. W. Jang, A. Umar, J. H. Lee
  • Year: 2013
  • Citations: 259
  1. Low-dimensional halide perovskites: review and issues
  • Authors: K. Hong, Q. V. Le, S. Y. Kim, H. W. Jang
  • Year: 2018
  • Citations: 257
  1. Palladium nanoparticles on assorted nanostructured supports: applications for Suzuki, Heck, and Sonogashira cross-coupling reactions
  • Authors: K. Hong, M. Sajjadi, J. M. Suh, K. Zhang, M. Nasrollahzadeh, H. W. Jang, et al.
  • Year: 2020
  • Citations: 252

 

Prof. Dr. Yawen Huang | Materials Science | Best Research Article Award

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Prof. Dr. Yawen Huang | Materials Science | Best Research Article Award

Academician/Research Scholar at Southwest University of Science and Technology, China

Yawen Huang is a distinguished professor and doctoral supervisor at the State Key Laboratory of Environment-friendly Energy Materials, Southwest University of Science and Technology. With a strong background in polymer science and materials engineering, she has made significant contributions to the development of self-healing polymer materials, low-dielectric resins, and anti-icing coatings. Her research integrates fundamental material design with real-world applications, addressing challenges in durability, environmental adaptability, and energy efficiency. As an active scholar, she has authored numerous high-impact journal articles and leads cutting-edge research projects focused on sustainable material innovation. In addition to her academic contributions, she plays a crucial role in mentoring young scientists and fostering interdisciplinary collaboration. Her work has gained international recognition, making her a key figure in advancing functional polymer materials.

Professional Profile

Education

Yawen Huang earned her doctoral degree in materials science and engineering from a prestigious institution, where she specialized in polymer chemistry and composite materials. Her early academic journey was marked by a deep interest in developing advanced functional materials with tailored properties for industrial and environmental applications. She pursued her undergraduate and master’s degrees in related fields, equipping herself with expertise in polymer synthesis, processing, and characterization techniques. During her Ph.D. research, she focused on dynamic-bond-based polymer networks, laying the foundation for her later breakthroughs in self-healing and anti-corrosion materials. She has also engaged in postdoctoral research at leading institutes, where she expanded her knowledge in nanomaterials and smart coatings. Her diverse educational background and rigorous scientific training have enabled her to pioneer novel material systems with high mechanical strength, self-repairing capabilities, and environmental resilience.

Professional Experience

Yawen Huang currently serves as a professor at Southwest University of Science and Technology, where she is also a doctoral supervisor at the State Key Laboratory of Environment-friendly Energy Materials. Over the years, she has led several research initiatives focused on designing high-performance polymeric materials for industrial and environmental applications. Her professional journey includes collaborations with leading national and international research institutions, where she has contributed to major projects in advanced material development. She has also held visiting scholar positions at renowned universities, strengthening her global research connections. Besides her academic roles, she actively participates in editorial boards and peer-review panels for high-impact scientific journals. Through her leadership, she has fostered interdisciplinary partnerships, bridging the gap between fundamental research and real-world material applications. Her dedication to innovation and mentorship has positioned her as a key influencer in the field of functional polymer materials.

Research Interests

Yawen Huang’s research focuses on the development of self-healing polymers, low-dielectric materials, and anti-icing coatings, with applications in energy, aerospace, and environmental sustainability. She has pioneered the design of smart coatings with self-repairing and superhydrophobic properties, which enhance durability and efficiency in extreme conditions. Her work also explores dynamic-bond-based polymer materials that exhibit superior mechanical strength, impact resistance, and recyclability. Additionally, she has developed novel gas-liquid reaction strategies for fabricating nanomaterials used in water purification and adsorption processes. Her research integrates fundamental polymer chemistry with practical applications, addressing key challenges in corrosion protection, thermal stability, and material sustainability. By combining experimental techniques with computational modeling, she continues to push the boundaries of functional material design. Her interdisciplinary approach has broad implications for industries seeking high-performance, eco-friendly material solutions.

Awards and Honors

Yawen Huang has received several prestigious awards and honors in recognition of her groundbreaking contributions to material science. She has been honored with national and international research excellence awards for her innovative work in self-healing polymers and low-dielectric materials. Her publications in top-tier journals have earned her accolades for scientific impact, and she has been invited as a keynote speaker at major conferences on polymer chemistry and sustainable materials. She has also secured competitive research grants from government agencies and industry partners, further validating the significance of her work. In addition to individual achievements, her research team has been recognized for pioneering advancements in smart coatings and recyclable polymer systems. Her dedication to scientific excellence and innovation continues to position her as a leading researcher in functional materials.

Conclusion

Yawen Huang is a strong contender for the Best Research Article Award, given their innovative contributions to self-healing and low-dielectric materials, high-quality journal publications, and leadership in research. However, assessing real-world impact, citation metrics, and interdisciplinary collaborations could further reinforce their candidacy. If the award prioritizes fundamental material science breakthroughs with strong potential for application, Huang’s research is highly deserving of recognition.

Publications Top Noted

  • Deng, Li et al., 2025, 0 citations
    “Cellulose-Based Transparent Superhydrophobic Coatings With a Four-Layer ‘Armor’ Structure for Anti-Fouling and Anti-Icing Applications”

  • Zhang, Weiliang et al., 2024, 0 citations
    “Preparation and properties of wear-resistant superhydrophobic coatings based on SiO2/aramid nanofibers ‘grape’ structure”

  • Xiong, Yang et al., 2024, 1 citation
    “Loading of aerogels in self-healable polyurea foam to prepare superhydrophobic tough coating with ultra-long freezing delay time and high durability”

  • Xiong, Yang et al., 2024, 0 citations
    “Preparation of superhydrophobic asymmetric vitrimer coating with high porosity and the key role of hierarchical pocket structure on long freeze delay time and high durability”

  • Zhang, Zihong et al., 2024, 0 citations
    “Ultralong-Term Durable Anticorrosive Coatings by Integration of Double-Layered Transfer Self-Healing Ability, Fe Ion-Responsive Ability, and Active/Passive Functional Partitioning”

  • Liu, Ying et al., 2023, 16 citations
    “Functional partition strategy in assistance by shear thinning/self-healing effect to prepare durable anti-corrosion coating”

  • Xiong, Yang et al., 2023, 3 citations
    “Hot-Pressing/Salt-Leaching Method Assisted by Boronic Ester Dynamic Bond to Prepare Vitrimer Foams with Ultra-Low Relative Permittivity and Superhydrophobic Performance”

  • Liang, Hengfei et al., 2023, 4 citations
    “Self-healable and transparent PDMS-g-poly(fluorinated acrylate) coating with ultra-low ice adhesion strength for anti-icing applications”

  • Huang, Yuanliang et al., 2022, 3 citations
    “Gas-Liquid Reactions to Synthesize Positively Charged Fe3O4 Nanoparticles on Polyurethane Sponge for Stable and Recyclable Adsorbents for the Removal of Phosphate from Water”

  • Liang, Hengfei et al., 2022, 1 citation
    “Correction: Construction of durable superhydrophobic and anti-icing coatings via incorporating boroxine cross-linked silicone elastomers with good self-healability”

 

Wenjing Yang | Materials Science and Engineering | Best Researcher Award

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Dr. Wenjing Yang | Materials Science and Engineering | Best Researcher Award

Research Associate, Inner Mongolia Metal Material Research Institute, China

Wenjing Yang is a dedicated Research Associate at the Inner Mongolia Metal Material Research Institute. With a passion for materials science and engineering, she has focused her career on the welding and processing of metal materials. After earning her doctorate from Northeastern University, Wenjing has continued to innovate in her field, contributing to the advancement of materials engineering through her research and professional experience.

Profile

Scopus

Evaluation of Wenjing Yang for the “Best Researcher Award”

Strengths for the Award:

Innovative Contributions: Wenjing Yang has made significant contributions to the field of Materials Science and Engineering, particularly in the area of metal welding and processing. The development of the double-sided friction stir processing (DFSP) technique is noteworthy, as it addresses common issues in traditional friction stir processing by eliminating the heat-affected zone (HAZ) and thermo-mechanically affected zone (TMAZ). This innovation has the potential to improve the mechanical properties of metal joints significantly.

Research Impact: The citation index of Yang’s work, particularly the articles cited 25 and 27 times, indicates a growing recognition and impact within the scientific community. The research on achieving high strength and ductility in aluminum alloys through DFSP has been well-received, reflecting the importance and relevance of the work.

Diverse Research Output: Yang has published multiple peer-reviewed articles in reputable journals, including “Materials Science and Engineering A” and “Heliyon.” This demonstrates a consistent output of high-quality research in the field.

Novel Theoretical Contributions: Yang’s work on the Cavity Growth Mechanism Map (CGMM) is another highlight. This theoretical framework for understanding superplastic deformation in aluminum alloys adds depth to the understanding of material behavior under specific conditions, contributing to the broader field of materials science.

Areas for Improvement:

Citation Index: While some of Yang’s work has been well-cited, there are publications with low or no citations. Increasing the visibility and impact of these papers through better dissemination, collaboration, or focusing on trending research topics could enhance overall citation metrics.

Collaborations and Professional Engagement: The absence of documented collaborations, industry projects, and professional memberships might be seen as a gap in Yang’s profile. Building a network through collaborations and professional organizations could strengthen research impact and provide additional opportunities for innovation.

Broader Research Scope: While Yang has made significant contributions to specific areas within materials science, expanding the research scope to include interdisciplinary studies or applications in other industries could increase the relevance and applicability of the research.

Education 🎓

Wenjing Yang completed her doctoral studies at Northeastern University, specializing in Materials Science and Engineering. Her academic background has equipped her with a strong foundation in the study and application of metal materials, particularly in the context of welding and processing technologies.

Professional Experience 🏢

Since November 2021, Wenjing Yang has been working at the Inner Mongolia Metal Material Research Institute. In her role as a Research Associate, she has been instrumental in leading several key research projects. Her work primarily revolves around developing innovative methods for the welding and processing of metal materials, significantly contributing to the institute’s research output.

Research Interests 🔍

Wenjing Yang’s research interests are centered around Materials Science and Engineering, with a particular focus on welding techniques and the processing of dissimilar metals. She has proposed novel methods, such as double-sided friction stir processing (DFSP) and a multi-layer plug and bolt connection for dissimilar metal butt joints, aimed at enhancing the mechanical properties and impact resistance of metal materials.

Awards and Recognitions 🏆

Wenjing Yang is a candidate for the Best Researcher Award at the World Top Scientists Awards. Her innovative contributions to the field of materials engineering, particularly her work on the Cavity Growth Mechanism Map (CGMM) for aluminum alloys, have earned her recognition within the scientific community.

Publications Top Notes📚

2024Improve the impact property in a novel butt joint of Ti/Al dissimilar metals – Published in Heliyon.

2021Parametric optimization for friction stir processing in Al-Zn-Mg-Cu alloy – Published in Materials and Manufacturing Processes.

Cited by: 25

2016Improvement of microstructure and mechanical properties of 7050-T7451 aluminum by a novel double-sided friction stir processing – Published in Materials Science Forum.

Cited by: 1

2017Achieving High Strength and Ductility in Double-Sided Friction Stir Processing 7050-T7451 Aluminum Alloy – Published in Materials Science and Engineering A.

Cited by: 27

2022Morphology Evolution of Cavity and Energy Dissipation during Superplastic Deformation of 7B04 Al-alloy – Published in Chinese Journal of Materials Research.

Cited by: 1

2024Effect of Sc on wettability of ER5356 welding wires and porosity of deposited metal – Published in ACS Omega.

Conclusion:

Wenjing Yang is a strong candidate for the “Best Researcher Award,” given the innovative contributions to the field of materials science, particularly in metal welding and processing. The development of new techniques like DFSP and theoretical contributions like the CGMM demonstrate a high level of expertise and innovation. However, there is room for growth in terms of expanding research collaborations, increasing professional engagement, and improving the citation impact across all publications. With continued focus and strategic enhancements, Yang’s research could have an even greater influence on the field.