Qixin Wan | Chemistry | Best Researcher Award

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Assoc. Prof. Dr. Qixin Wan | Chemistry | Best Researcher Award

Associate Professor from Jiangxi Science and Technology Normal University, China

Dr. Qixin Wan is a highly accomplished academic and researcher, currently serving as an Associate Professor at the Jiangxi Provincial Key Laboratory of Advanced Electronic Materials and Devices, affiliated with Jiangxi Science and Technology Normal University in China. He obtained his Ph.D. in Electronic Science and Technology from the prestigious Huazhong University of Science and Technology (HUST), where he worked under the supervision of Professor Changqing Chen. With a career rooted in advanced materials science, Dr. Wan has dedicated himself to exploring and solving complex interfacial phenomena in novel materials. He has authored more than 20 SCI-indexed research papers published in internationally recognized journals such as Angewandte Chemie International Edition, ACS Applied Materials & Interfaces, and Optics Express. His work integrates theoretical, computational, and experimental approaches, contributing significantly to fields including optoelectronics, photonics, and semiconductors. Dr. Wan is recognized for his strong command of first-principles modeling, machine learning applications, and reaction mechanisms, all of which support the development of innovative materials and technologies. His interdisciplinary expertise places him at the intersection of physics, chemistry, and engineering, making his contributions valuable across multiple domains. He continues to lead impactful research that advances the understanding and application of cutting-edge materials.

Professional Profile

Education

Dr. Qixin Wan has followed a comprehensive and robust educational path that has laid a solid foundation for his distinguished research career. He began his academic journey at Nanchang University, where he completed his Bachelor of Science in Materials Science and Engineering in 2004. Building on his undergraduate experience, he pursued a Master of Engineering in Materials Physics and Chemistry at the same university, completing his degree in 2007 under the mentorship of Professor Fengyi Jiang. His deep interest in electronics and material interfaces led him to undertake a Ph.D. in Electronic Science and Technology at Huazhong University of Science and Technology (HUST), one of China’s leading institutions in science and engineering. From 2013 to 2019, he conducted his doctoral research at the Wuhan National Laboratory for Optoelectronics, where he was supervised by Professor Changqing Chen. His doctoral studies focused on the rational design of novel materials and interfacial physics, equipping him with high-level theoretical knowledge and experimental capabilities. This educational trajectory reflects Dr. Wan’s commitment to academic excellence and his steady progression toward becoming a thought leader in materials science. His education not only enriched his technical skills but also prepared him to contribute innovatively to scientific research and higher education.

Professional Experience

Dr. Qixin Wan’s professional career spans over 15 years of continuous growth and contribution in academia, particularly in advanced materials and optoelectronics research. He began his academic tenure at Jiangxi Science and Technology Normal University shortly after completing his master’s degree, initially serving as an instructor in the Key Laboratory for Optoelectronics and Communication of Jiangxi Province. From 2007 to 2023, he worked as an Instructor and Assistant Professor, engaging in both teaching and research responsibilities. His work during this period contributed significantly to the laboratory’s reputation in semiconductor and materials research. In December 2023, Dr. Wan was promoted to the position of Associate Professor at the Jiangxi Provincial Key Laboratory of Advanced Electronic Materials and Devices. This advancement marked a formal recognition of his contributions to scientific innovation and academic leadership. In his current role, Dr. Wan continues to lead research projects, mentor students, and collaborate on interdisciplinary initiatives. His career has been characterized by steady progress, long-term institutional commitment, and a continuous push toward innovation in the design and analysis of electronic materials. His professional experience has made him a respected figure in materials research and education, both locally and internationally.

Research Interests

Dr. Qixin Wan’s research interests lie at the forefront of advanced materials science and electronic device innovation. His work primarily focuses on the rational design of novel materials and the fundamental understanding of interfacial phenomena in electronic systems. Among his key areas of interest are first-principles modeling, which allows for atomistic-level predictions of material behavior; microkinetic simulation and machine learning, used to analyze complex reaction networks; and interface physics, crucial for optimizing device performance in optoelectronic applications. Additionally, Dr. Wan is deeply involved in photoelectric semiconductor physics, seeking to enhance the efficiency and durability of next-generation electronic and photonic devices. He also investigates reaction mechanisms at the molecular and atomic levels, exploring how material surfaces and interfaces influence chemical processes. These interests form a cohesive, interdisciplinary research agenda that integrates theoretical and computational modeling with practical device engineering. Dr. Wan’s curiosity and methodical approach have led him to address key scientific challenges, particularly those related to energy transfer, charge dynamics, and material degradation. His research not only contributes to the fundamental understanding of material science but also supports applied innovations in fields such as renewable energy, photonics, and electronics.

Research Skills

Dr. Qixin Wan possesses a comprehensive set of research skills that empower him to operate at the cutting edge of materials science and electronic engineering. His proficiency in first-principles modeling allows him to simulate and predict the behavior of complex materials at the atomic and molecular levels, which is critical for designing innovative compounds. He is highly skilled in microkinetic simulations, enabling him to understand reaction rates and mechanisms under various physical and chemical conditions. Dr. Wan also incorporates machine learning algorithms into his work, using data-driven approaches to accelerate material discovery and optimize experimental design. His technical toolkit includes advanced techniques in interface physics, particularly the study of electron and energy transport across heterogeneous materials. Additionally, he is adept in experimental methods related to photoelectric and semiconductor devices, often linking computational predictions with laboratory outcomes. These skills are complemented by his experience with scientific software platforms and programming languages used in material modeling. His interdisciplinary capabilities allow him to bridge gaps between theory, simulation, and experimental validation. Dr. Wan’s diverse skill set equips him to tackle complex research problems, lead collaborative projects, and contribute effectively to the advancement of optoelectronic technologies and materials innovation.

Awards and Honors

While specific awards and honors were not explicitly listed in the provided profile, Dr. Qixin Wan’s academic and research achievements speak to a career worthy of distinction. His promotion to Associate Professor at a leading provincial key laboratory in China is in itself a significant professional milestone, reflecting institutional recognition of his contributions to the field of materials science and optoelectronics. Furthermore, the consistent publication of over 20 SCI-indexed papers in prestigious journals such as Angewandte Chemie International Edition, ACS Applied Materials & Interfaces, Optics Express, and others, showcases his sustained research excellence and peer-reviewed validation of his work. Publishing in such high-impact journals typically reflects innovation, technical quality, and relevance—key metrics often considered for academic awards. His research impact within the field is further amplified by the diversity and scope of his interdisciplinary studies. In the future, Dr. Wan’s continued contributions and expanding influence are likely to attract additional recognitions from academic societies, research foundations, and innovation-driven organizations. As his work begins to intersect more directly with applied technologies in energy, healthcare, and environmental science, opportunities for competitive national and international honors are likely to increase.

Conclusion

Dr. Qixin Wan stands out as a forward-thinking researcher whose work bridges theoretical modeling, material design, and practical applications in electronic and photonic devices. His academic background, enriched by a Ph.D. from Huazhong University of Science and Technology and two earlier degrees from Nanchang University, has prepared him to lead pioneering research in interface physics and materials innovation. Over his professional career, he has progressed steadily, from instructor to associate professor, and has produced an impressive body of work published in high-impact journals. His research interests are at the intersection of multiple disciplines, encompassing semiconductor physics, microkinetic simulations, and machine learning. These diverse but interrelated pursuits allow him to address complex scientific problems with a high degree of precision and creativity. Although further recognition in the form of awards and honors may be forthcoming, his academic and research trajectory already places him among the most promising scientists in his field. With his expanding expertise and commitment to interdisciplinary collaboration, Dr. Wan is poised to make significant contributions to the global research community, particularly in life sciences, materials science, and applied electronics. He represents the type of scholar whose work will continue to shape the future of science and technology.

Publications Top Notes

  1. Synergizing Mg Single Atoms and Ru Nanoclusters for Boosting the Ammonia Borane Hydrolysis to Produce Hydrogen

    • Authors: Xie Shumin, Tian Shuheng, Yang Jialei, MA Ding, Zhao X. S.

    • Year: 2025

    • Citations: 1

  2. Unexpected Enhanced Thermal Conductivity of GaxIn₁₋ₓSb Ternary Alloys

    • Authors: Zhu Xiaolu, Zhang Yu, Kang Chao, Qin Guangzhao, Xiong Zhihua

    • Year: 2023

    • Citations: 3

  3. Synergistic Effect of Guanidinium Tetrafluoroborate Boosting Photovoltaic Performance of Perovskite Solar Cells

    • Authors: Wu Baifeng, Wang Xiaofeng, Xia Xuefeng, Li Yangsheng, Li Fan

    • Year: 2022

    • Citations: 5

  4. Functionalized Ionic Liquid-Crystal Additive for Perovskite Solar Cells with High Efficiency and Excellent Moisture Stability

    • Authors: Xia Xuefeng, Peng Jiayi, Wan Qixin, Zhao Jie, Li Fan

    • Year: 2021

    • Citations: 34

Prasanta Roy | Organic Chemistry | Best Researcher Award

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Assist. Prof. Dr. Prasanta Roy | Organic Chemistry | Best Researcher Award

Assistant Professor (International Faculty Member) at School of Chemical Engineering, Yeungnam University, Republic of Korea.

Dr. Prasanta Roy is an accomplished researcher in synthetic organic chemistry, specializing in asymmetric synthesis, catalytic transformations, and bioactive molecule synthesis. With extensive postdoctoral experience across leading institutions in China, India, and South Korea, he has contributed significantly to organic synthesis through innovative methodologies. His expertise spans N-heterocycle synthesis, enantioselective transformations, and transition metal-catalyzed reactions. Currently serving as an Assistant Professor at Yeungnam University, he continues to advance research in transition metal-catalyzed C-H activation and annulation reactions. Dr. Roy’s international research collaborations and academic contributions underscore his commitment to advancing the field of organic chemistry.

Professional Profile

Education

Dr. Prasanta Roy earned his Ph.D. in Synthetic Organic Chemistry from the Indian Institute of Technology (IIT) Guwahati in 2016, where he worked on copper oxide nanoparticle-assisted synthesis of 1,4-triazoles and N-heterocycles under the supervision of Prof. A. T. Khan and Prof. Bhisma Kumar Patel. He completed his M.Sc. in Organic Chemistry from Visva-Bharati University in 2010 and his B.Sc. in Chemistry from the University of Burdwan in 2008. His academic journey reflects a strong foundation in organic synthesis, enabling him to develop expertise in asymmetric catalysis, multicomponent reactions, and medicinal chemistry, which have remained central to his research contributions.

Professional Experience

Dr. Roy has held multiple prestigious research positions globally. He began his postdoctoral research at the Chinese Academy of Sciences (2016-2018), focusing on asymmetric synthesis and kinetic resolution strategies. He later joined Yunnan University (2019-2021), where he worked on bioactive molecule synthesis and medicinal chemistry. At IIT Kanpur (2021-2022), he specialized in dynamic kinetic resolution and asymmetric organic synthesis. From 2022 to early 2024, he contributed to transition metal-catalyzed organic synthesis at Yeungnam University, South Korea. In March 2024, he was appointed as an Assistant Professor at Yeungnam University, continuing his work in catalysis and organic synthesis.

Research Interests

Dr. Roy’s research focuses on synthetic organic chemistry, particularly in asymmetric synthesis, transition metal-catalyzed reactions, and medicinal chemistry. He is particularly interested in developing new methodologies for enantioselective transformations, asymmetric transfer hydrogenation, and C-H bond activation. His work also extends to multicomponent reactions for the synthesis of heterocyclic compounds, with applications in drug discovery and pharmaceutical chemistry. His interdisciplinary approach integrates nanocatalysis and organocatalysis to create sustainable and efficient synthetic routes for complex organic molecules.

Research Skills

Dr. Roy possesses advanced skills in organic synthesis, asymmetric catalysis, transition metal-catalyzed transformations, and kinetic resolution. He is proficient in various chromatographic and spectroscopic techniques, including NMR, HPLC, and mass spectrometry, essential for structural elucidation and reaction optimization. His expertise in computational chemistry and mechanistic studies enables him to design novel catalysts and reaction pathways. Additionally, he has experience in medicinal chemistry, focusing on synthesizing bioactive compounds with potential pharmaceutical applications. His multidisciplinary research approach combines synthetic methodologies with analytical techniques to develop efficient and selective chemical transformations.

Awards and Honors

Dr. Roy’s contributions to organic chemistry have been recognized through various fellowships and research grants. He has received postdoctoral fellowships from the Chinese Academy of Sciences and IIT Kanpur. His work in asymmetric catalysis and bioactive molecule synthesis has been published in reputed international journals. As an emerging leader in organic synthesis, he has actively contributed to academic conferences, presenting his research at international symposiums. His recognition in the field continues to grow, reflecting his impact on synthetic methodologies and catalysis.

Conclusion

Dr. Prasanta Roy is a distinguished researcher in synthetic organic chemistry with a strong international research background. His expertise in asymmetric synthesis, transition metal catalysis, and medicinal chemistry positions him as a leading contributor to modern organic synthesis. With an extensive postdoctoral research portfolio and recent appointment as an Assistant Professor, he continues to advance research in catalysis and sustainable chemical transformations. Strengthening his publication impact, securing independent research grants, and expanding his mentorship activities will further enhance his academic and professional contributions. His dedication to innovative organic synthesis methodologies makes him a strong candidate for research excellence recognition.

Publication Top Notes

  1. Synthesis of tetra-substituted pyrroles, a potential phosphodiesterase 4B inhibitor, through nickel (II) chloride hexahydrate catalyzed one-pot four-component reaction

    • Authors: AT Khan, M Lal, PR Bagdi, RS Basha, P Saravanan, S Patra
    • Journal: Tetrahedron Letters
    • Volume: 53
    • Issue: 32
    • Pages: 4145-4150
    • Year: 2012
    • Citations: 93

  2. Camphorsulfonic acid catalyzed one-pot three-component reaction for the synthesis of fused quinoline and benzoquinoline derivatives

    • Authors: R Gattu, PR Bagdi, RS Basha, AT Khan
    • Journal: The Journal of Organic Chemistry
    • Volume: 82
    • Issue: 23
    • Pages: 12416-12429
    • Year: 2017
    • Citations: 35

  3. An oxidative cross-coupling reaction of 4-hydroxydithiocoumarin and amines/thiols using a combination of I₂ and TBHP: Access to lead molecules for biomedical applications

    • Authors: K Mahato, N Arora, PR Bagdi, R Gattu, SS Ghosh, AT Khan
    • Journal: Chemical Communications
    • Volume: 54
    • Issue: 12
    • Pages: 1513-1516
    • Year: 2018
    • Citations: 28

  4. Access to enantioenriched compounds bearing challenging tetrasubstituted stereocenters via kinetic resolution of auxiliary adjacent alcohols

    • Authors: S Niu, H Zhang, W Xu, PR Bagdi, G Zhang, J Liu, S Yang, X Fang
    • Journal: Nature Communications
    • Volume: 12
    • Article Number: 3735
    • Year: 2021
    • Citations: 19

  5. Copper oxide nanoparticle mediated ‘click chemistry’ for the synthesis of mono-, bis- and tris-triazole derivatives from 10,10-dipropargyl-9-anthrone as a key building block

    • Authors: PR Bagdi, RS Basha, PK Baruah, AT Khan
    • Journal: RSC Advances
    • Volume: 4
    • Issue: 21
    • Pages: 10652-10659
    • Year: 2014
    • Citations: 17

  6. One-pot three-component regioselective synthesis of C1-functionalised 3-arylbenzo[f]quinoline

    • Authors: R Gattu, RS Basha, PR Bagdi, AT Khan
    • Journal: RSC Advances
    • Volume: 6
    • Issue: 14
    • Pages: 11675-11682
    • Year: 2016
    • Citations: 16

  7. Synthesis of 2-triazolyl-imidazo[1,2-a]pyridine through a one-pot three-component reaction using a nano copper oxide assisted click-catalyst

    • Authors: PR Bagdi, RS Basha, AT Khan
    • Journal: RSC Advances
    • Volume: 5
    • Issue: 75
    • Pages: 61337-61344
    • Year: 2015
    • Citations: 16

  8. Stereodivergent access to enantioenriched epoxy alcohols with three stereogenic centers via ruthenium-catalyzed transfer hydrogenation

    • Authors: Z Zhao, PR Bagdi, S Yang, J Liu, W Xu, X Fang
    • Journal: Organic Letters
    • Volume: 21
    • Issue: 14
    • Pages: 5491-5494
    • Year: 2019
    • Citations: 13

  9. K₂CO₃ catalyzed regioselective synthesis of thieno[2,3-b]thiochromen-4-one oximes: Access to the corresponding amine and nitroso derivatives

    • Authors: K Mahato, PR Bagdi, AT Khan
    • Journal: Organic & Biomolecular Chemistry
    • Volume: 15
    • Issue: 26
    • Pages: 5625-5634
    • Year: 2017