Shihai Sun | High entropy alloy | Best Researcher Award

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Best Researcher Award

Shihai Sun
Beijing institute of technology
Shihai Sun
Affiliation Beijing institute of technology
Country China
Scopus ID 55931352000
Documents 45
Citations 2290
h-index 21
Subject Area High entropy alloy
Event International Research Scientist Awards

The Best Researcher Award recognition highlights the scholarly contributions and research impact of Shihai Sun, a researcher affiliated with Beijing institute of technology in China. The academic profile reflects sustained contributions in the field of high entropy alloy research, including publications, citation impact, and interdisciplinary materials science investigations. The recognition is associated with the International Research Scientist Awards program, which acknowledges notable academic achievements and research excellence across multiple scientific domains.[1]

Abstract

This article presents an academic overview of the research accomplishments and scholarly contributions of Shihai Sun within the field of high entropy alloy research. The profile demonstrates a significant research footprint characterized by peer-reviewed publications, citation performance, and scientific engagement in advanced materials engineering. The available bibliometric indicators, including citation count and h-index, indicate sustained visibility and relevance within the international scientific community. The recognition associated with the Best Researcher Award reflects both academic productivity and the broader impact of contributions to materials science and engineering research.[1][2]

Keywords

High entropy alloy, Materials science, Advanced engineering materials, Metallurgy, Research impact, Scientific recognition, International Research Scientist Awards

Introduction

Research involving high entropy alloys has gained increasing attention due to the potential applications of these advanced materials in aerospace, energy systems, structural engineering, and high-performance industrial environments. Investigations in this field frequently focus on microstructural optimization, mechanical performance, corrosion resistance, and thermal stability. Researchers contributing to this domain play a significant role in the advancement of next-generation metallic systems and engineering technologies.[2]

Shihai Sun has contributed to this research area through scholarly publications and collaborative scientific studies associated with Beijing institute of technology. The available academic metrics indicate measurable research visibility, including a substantial citation record and a recognized h-index within the Scopus database. These indicators are commonly utilized to evaluate research dissemination and scholarly influence across scientific disciplines.[1]

Research Profile

The research profile of Shihai Sun reflects involvement in materials engineering and high entropy alloy investigations with emphasis on alloy composition, phase stability, microstructural behavior, and functional performance. The documented publication portfolio includes articles indexed within major scientific databases and demonstrates active participation in internationally recognized scholarly communication channels.[1]

The Scopus author profile identifies 45 indexed documents with approximately 2290 citations and an h-index of 21. These metrics suggest sustained academic engagement and influence within the field of materials science research. Bibliometric indicators are frequently applied in evaluating scientific productivity, collaboration, and research impact in academic assessment frameworks.[1]

Research Contributions

The research contributions associated with Shihai Sun primarily involve advanced metallic materials and high entropy alloy systems. High entropy alloys are characterized by complex elemental compositions and unique structural behaviors that may improve mechanical strength, corrosion resistance, thermal endurance, and wear properties. Research in this area contributes to the development of materials suitable for demanding engineering environments.[3]

Scholarly work in the field commonly integrates experimental metallurgy, computational modeling, thermodynamic analysis, and advanced characterization techniques. Such multidisciplinary methodologies support the identification of novel alloy systems and provide insights into phase formation and structural performance under varying operational conditions.[4]

  • Investigation of high entropy alloy microstructures and phase evolution.
  • Evaluation of mechanical and thermal properties of advanced metallic systems.
  • Research collaboration within materials science and engineering domains.
  • Publication of peer-reviewed scientific articles in indexed journals.
  • Contribution to the broader advancement of alloy design methodologies.

Publications

The publication portfolio associated with Shihai Sun includes scholarly contributions relevant to high entropy alloys and materials engineering. Representative research themes involve alloy synthesis, microstructural analysis, corrosion resistance, mechanical behavior, and advanced material characterization methods. The research output contributes to the expanding literature on multifunctional alloy systems and engineering materials.[1]

  1. Research articles related to high entropy alloy systems and metallurgical performance analysis.
  2. Studies involving phase transformation and advanced structural materials.
  3. Publications addressing thermal stability and corrosion resistance in alloy systems.
  4. Collaborative scientific investigations published in indexed engineering journals.

Selected publications and associated DOI records demonstrate integration within internationally accessible scholarly databases and citation systems.[5]

Research Impact

Research impact may be assessed through citation activity, publication dissemination, scholarly collaboration, and influence on subsequent investigations. The citation count associated with the research profile of Shihai Sun indicates that published work has received attention within the broader scientific community. Citation metrics also reflect continued relevance within materials engineering and alloy research domains.[1]

The h-index value of 21 further suggests that multiple publications have achieved consistent citation performance. Within academic evaluation systems, such indicators are commonly interpreted as evidence of research continuity, scholarly engagement, and scientific visibility across international research networks.[2]

Award Suitability

The academic profile of Shihai Sun demonstrates characteristics frequently associated with research recognition programs, including publication productivity, citation impact, scientific specialization, and contribution to emerging engineering materials research. The field of high entropy alloy research remains strategically relevant due to its applications in advanced manufacturing, aerospace engineering, and high-performance industrial systems.[3]

Participation in international scholarly activities and publication within indexed scientific databases further supports the suitability of the researcher for recognition within the International Research Scientist Awards framework. The documented research metrics indicate sustained academic contribution and measurable scientific visibility within the materials science community.

Conclusion

The Best Researcher Award article summarizes the academic profile and scientific contributions of Shihai Sun in the field of high entropy alloy research. The documented bibliometric indicators, publication record, and citation activity collectively demonstrate active engagement in advanced materials science investigations. Through continued scholarly contributions and participation in engineering research, the profile reflects measurable academic influence and international scientific visibility.[1]

References

  1. Elsevier. (n.d.). Scopus author details: Shihai Sun, Author ID 55931352000. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=55931352000
  2. Google Scholar. (n.d.). Research citations and publication metrics associated with Shihai Sun.
    https://scholar.google.com/citations?user=Lm9hNf4AAAAJ&hl=en
  3. Sun, S.H., Hagihara, K., & Nakano, T. (2018).
    Effect of scanning strategy on texture formation in Ni-25 at.% Mo alloys fabricated by selective laser melting.
    Materials & Design, 140, 307–316.
    https://doi.org/10.1016/j.matdes.2017.11.060
  4. Ishimoto, T., Hagihara, K., Hisamoto, K., Sun, S.H., & Nakano, T. (2017).
    Crystallographic texture control of beta-type Ti–15Mo–5Zr–3Al alloy by selective laser melting for the development of novel implants with a biocompatible low Young’s modulus.
    https://doi.org/10.1016/j.scriptamat.2016.12.038
  5. Sun, S.H., Ishimoto, T., Hagihara, K., Tsutsumi, Y., Hanawa, T., & Nakano, T. (2018).
    Excellent mechanical and corrosion properties of austenitic stainless steel with a unique crystallographic lamellar microstructure via selective laser melting.
    https://doi.org/10.1016/j.scriptamat.2018.09.017

Bhanu Bhusan Khatua | Energy Materials | Best Researcher Award

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Prof. Dr. Bhanu Khatua | Energy Materials | Best Researcher Award

Professor , Indian Institute of Technology Kharagpur , India

Prof. Dr. Bhanu Bhusan Khatua is a highly accomplished researcher whose work in polymer science, nanomaterials, and energy harvesting systems positions him as a leader in materials science. His high-impact publications, prestigious awards, and consistent research funding reflect a robust and mature research portfolio. He has demonstrated exceptional academic mentorship and built meaningful global collaborations that have amplified his research footprint. His interdisciplinary approach addresses both fundamental science and real-world applications, aligning strongly with the goals of a Best Researcher Award.

Professional Profile

🎓 Educational Background

Prof. Dr. Bhanu Bhusan Khatua holds a Ph.D. in Polymer Science and Engineering from the Materials Science Centre, Indian Institute of Technology (IIT) Kharagpur, awarded in 2001. His academic journey began with a B.Sc. with Honours in Chemistry from Vidyasagar University in 1994, followed by an M.Sc. in Chemistry in 1996 from the same institution, where he graduated First Class First. His outstanding academic performance earned him the University Gold Medal and the Biswanath De Gold Medal for securing the top rank.

🧑‍🏫 Professional Experience

Prof. Khatua has been an Associate Professor at the Materials Science Centre, IIT Kharagpur since August 2013. He previously served as an Assistant Professor at the same institute from 2007 to 2013. His industrial research experience includes working as a Research Scientist at GE India Technology Centre, Bangalore (2004–2007). He has also completed prestigious postdoctoral fellowships at Technion – Israel Institute of Technology (2000–2002) and POSTECH, South Korea (2002–2004).

🔬 Research Focus

Prof. Khatua’s research is primarily centered on Energy Materials, including piezoelectric, triboelectric, and hybrid nanogenerators for energy harvesting and supercapacitors for energy storage. He is also active in developing EMI shielding materials using polymeric and hybrid composites. Additional areas of specialization include polymer/clay nanocomposites, morphology control in incompatible polymer blends, and electrically conducting polymeric PTCR composites.

🛠️ Skills and Expertise

Prof. Khatua has deep expertise in polymer science, nanocomposites, and functional materials. He is skilled in material synthesis, characterization, and device-level application, with a strong focus on bridging fundamental science with industrial relevance. He is also known for his leadership in interdisciplinary research, mentoring, and collaboration.

🏅 Awards & Honours

Prof. Dr. Bhanu Bhusan Khatua has received numerous prestigious awards and recognitions throughout his academic and research career. He is a Fellow of the West Bengal Academy of Science and Technology (WAST) 🧪, honored for his significant contributions to science and technology in the region. In 2022, he was awarded the Materials Research Society of India (MRSI) Medal 🥇 in recognition of his outstanding work in the field of materials science. His global impact was acknowledged when he was listed among the World’s Top 2% Scientists 🌍 in 2021, based on a comprehensive citation analysis by Stanford University.

Publication Top Notes

1. Title: Effect of organoclay platelets on morphology of nylon-6 and poly (ethylene-ran-propylene) rubber blends
Authors: BB Khatua, DJ Lee, HY Kim, JK Kim
Citations: 448
Year: 2004

2. Title: An approach to design highly durable piezoelectric nanogenerator based on self‐poled PVDF/AlO‐rGO flexible nanocomposite with high power density and energy conversion efficiency
Authors: SK Karan, R Bera, S Paria, AK Das, S Maiti, A Maitra, BB Khatua
Citations: 422
Year: 2016

3. Title: Self-powered flexible Fe-doped RGO/PVDF nanocomposite: an excellent material for a piezoelectric energy harvester
Authors: SK Karan, D Mandal, BB Khatua
Citations: 410
Year: 2015

4. Title: Polystyrene/MWCNT/graphite nanoplate nanocomposites: efficient electromagnetic interference shielding material through graphite nanoplate–MWCNT–graphite nanoplate networking
Authors: S Maiti, NK Shrivastava, S Suin, BB Khatua
Citations: 336
Year: 2013

5. Title: Nature driven bio‐piezoelectric/triboelectric nanogenerator as next‐generation green energy harvester for smart and pollution free society
Authors: S Maiti, SK Karan, JK Kim, BB Khatua
Citations: 206
Year: 2019

6. Title: Highly exfoliated eco-friendly thermoplastic starch (TPS)/poly (lactic acid)(PLA)/clay nanocomposites using unmodified nanoclay
Authors: B Ayana, S Suin, BB Khatua
Citations: 195
Year: 2014

7. Title: Nature driven spider silk as high energy conversion efficient bio-piezoelectric nanogenerator
Authors: SK Karan, S Maiti, O Kwon, S Paria, A Maitra, SK Si, Y Kim, JK Kim, BB Khatua
Citations: 180
Year: 2018

8. Title: Recent advances in self‐powered tribo‐/piezoelectric energy harvesters: all‐in‐one package for future smart technologies
Authors: SK Karan, S Maiti, JH Lee, YK Mishra, BB Khatua, JK Kim
Citations: 178
Year: 2020

9. Title: Bio-waste onion skin as an innovative nature-driven piezoelectric material with high energy conversion efficiency
Authors: S Maiti, SK Karan, J Lee, AK Mishra, BB Khatua, JK Kim
Citations: 175
Year: 2017

10. Title: Designing high energy conversion efficient bio-inspired vitamin assisted single-structured based self-powered piezoelectric/wind/acoustic multi-energy harvester with remarkable output
Authors: SK Karan, S Maiti, AK Agrawal, AK Das, A Maitra, S Paria, A Bera, R Bera, BB Khatua
Citations: 147
Year: 2019

Conclusion

In conclusion, Prof. Dr. Bhanu Bhusan Khatua is a highly suitable and deserving candidate for the Best Researcher Award. His extensive publication record, global impact, innovation, mentorship, and recognitions collectively present a compelling case. While he can further elevate his profile through deeper industry engagement and global leadership roles, his existing credentials already meet and exceed many benchmarks typical of such honors. Awarding him would recognize both past excellence and future promise.