Year: 2025

Education

Dr. Sudalaimuthu earned his Ph.D. in Mechanical Engineering (Solar Desalination) from Anna University (2021–2025), where he specialized in experimental solar still enhancements using nanomaterials. He completed his M.E. in Thermal Engineering from Government College of Technology, Coimbatore (2016–2018), funded by a TEQIP Phase-2 scholarship. His undergraduate degree, B.E. in Mechanical Engineering (2013–2016), was from the National Engineering College, Tamil Nadu. Prior to that, he received a Diploma in Mechanical Engineering (2010–2013) from Sankar Polytechnic College. His academic foundation is rooted in strong theoretical and practical knowledge of thermodynamics, heat transfer, renewable energy, and sustainable engineering systems. Each stage of his education has contributed to his focus on waste-to-energy conversion, solar thermal systems, and nanomaterials for clean water production. His early interest in solar technology and circular economy applications was reinforced through hands-on research and guided thesis work under esteemed professors.

Professional Experience

Dr. Sudalaimuthu’s professional experience integrates research, teaching, and industry practice. From June 2021 to June 2025, he served as a Research Fellow at KPR Institute of Engineering and Technology, focusing on solar desalination and nanomaterials, supported by an institutional research fellowship. He previously worked in HVAC maintenance at ETA Engineering Pvt. Ltd. (2020–2021) and served as a Teaching Associate at KPR Institute and part-time lecturer at Government College of Technology. He taught renewable energy systems, HVAC, power plant engineering, and thermal sciences, and managed labs including IC engines and thermal systems. His Ph.D. research contributed new knowledge in solar still design, especially involving bio-wick and MXene-coated surfaces. With practical exposure to biodiesel production, lab-scale pyrolysis, and thermochemical reactors, he combines deep experimental insights with strong pedagogical skills, preparing him to lead advanced interdisciplinary research in green energy and sustainable engineering.

Research Focus

Dr. Sudalaimuthu’s research is centered on sustainable water production and renewable energy integration. His Ph.D. focuses on passive inclined solar stills enhanced with localized interfacial evaporation techniques and MXene-based nanocoatings under varying flow conditions. He has developed novel approaches for improving freshwater yield from solar desalination systems using nanostructured bio-wick materials. His work also extends to green hydrogen generation via agro-waste valorization, catalytic pyrolysis of plastic waste, and sustainable fuel production. He has investigated emission-reduction strategies for CI engines using alternative fuels like Bael biodiesel and plastic-derived oils. His studies employ experimental, numerical (RSM, ANN), and optimization tools to understand energy and exergy dynamics in renewable systems. In the broader scope, he aims to create scalable, low-cost technologies for food preservation, water purification, and waste-to-energy conversion, aligning with the goals of a circular economy and net-zero carbon emissions. His work bridges thermal science, material science, and environmental engineering.

Publications to Notes

Enhancement and prediction of a stepped solar still productivity integrated with paraffin wax enriched with nano-additives
Citations: 57
Year: 2023

Prediction and performance optimisation of a DI CI engine fuelled diesel–Bael biodiesel blends with DMC additive using RSM and ANN: Energy and exergy analysis
Citations: 45
Year: 2023

Performance analysis on single slope solar still with absorber coated using iron oxide nanoparticles at different water thickness
Citations: 15
Year: 2023

The clean energy aspect of plastic waste — hydrogen gas production, CO₂ reforming, and plastic waste management coincide with catalytic pyrolysis
Citations: 14
Year: 2023

Experimental investigation of inclined solar still through localized interfacial evaporation using nano enhanced Bio wick under disparate flow rate Citations: 12
Year: 2024

Conclusion

Dr. Pitchaiah Sudalaimuthu is highly suitable for the Best Researcher Award, particularly in categories related to sustainable energy systems, green technologies, or emerging environmental scientists. His portfolio showcases technical depth, research originality, and a commitment to impactful science, addressing pressing global challenges like water scarcity and plastic waste. With continued strategic development in global collaboration and translational output, he is poised to become a recognized leader in clean energy research. His profile aligns well with the award’s vision of innovation, sustainability, and societal benefit.

Jorge Alonso Uribe-Calderon | Nano Biomaterials | Best Researcher Award

Published on 24/07/202501/08/2025 by MTE Awards

Prof. Jorge Alonso Uribe-Calderon | Nano Biomaterials | Best Researcher Award

Researcher at Yucatan Scientific Research Center | Mexico

Dr. Jorge Alonso Uribe-Calderon is a professor at the Centro de Investigación Científica de Yucatán (CICY) in Mérida, Mexico. With more than 20 years of experience in materials science, he has focused on polymeric composites, nanomaterials, and sustainable biopolymers. He has completed his undergraduate studies in Chemical Engineering at Universidad Autónoma de Yucatán and advanced his academic training with a Master’s, Ph.D., and Postdoctoral work at McGill University in Canada. Dr. Uribe-Calderon has authored over 69 scientific papers with more than 1900 citations and an h-index of 19. He has supervised numerous graduate and undergraduate theses, and he is also active in course instruction on topics such as polymer degradation, surface physicochemistry, and nanomaterials. His interdisciplinary expertise and dedication to polymer science have made significant contributions to both academic knowledge and industrial application, especially in the field of green and functional materials.

Professional Profiles

Education

Dr. Uribe-Calderon began his academic journey at the Universidad Autónoma de Yucatán (UADY), where he earned a Bachelor’s degree in Chemical Engineering (1989–1994). He later joined McGill University in Montreal, Canada, completing a Master’s in Chemical Engineering (2001–2003), followed by a Ph.D. in the same discipline (2003–2008). His doctoral research explored the synthesis and processing of polymer-clay nanocomposites. From 2008 to 2010, he completed postdoctoral studies at McGill University, continuing his work on nanocomposites, nanoparticle modification, and polymer processing. His academic background combines chemical engineering principles with specialized training in polymer science, enabling him to contribute significantly to both fundamental research and applied materials development. The international scope of his education helped build a global perspective in his research, teaching, and collaborations, fostering long-term contributions to polymeric materials and nanocomposites.

Professional Experience

Dr. Uribe-Calderon has held several academic and research positions in both Canada and Mexico. From 1996 to 2001, he served as an Academic Technician at CICY, focusing on polymer processing and material characterization while engaging in student mentorship and industrial consulting. Between 1999 and 2001, he taught undergraduate courses in polymer product design at Universidad Modelo in Mérida. From 2001 to 2008, he worked as a Research Assistant at McGill University, contributing to major projects on polymer nanocomposites. He then continued as an Associate Researcher at McGill University (2010–2011), before returning to CICY, where he currently holds a Professorship. Over the years, he has developed a strong research portfolio that bridges theory and application. His work emphasizes sustainability, innovation, and the functionalization of polymeric materials, particularly through nanocomposites and biopolymer formulations.

Research Focus

Dr. Uribe-Calderon’s research revolves around the development, processing, and characterization of polymeric composites and nanocomposites. He focuses on the integration of functional nanoparticles such as graphene oxide, nanoclay, and cellulose nanocrystals into polymer matrices to enhance mechanical, thermal, and barrier properties. His interest in biopolymers and polymer blends aligns with goals for sustainable material development. He employs both chemical modification techniques and physical blending strategies to optimize the interface compatibility and dispersion of nanofillers. Additionally, his research includes studies on polymer degradation, thermal stability, and the physicochemical behavior of materials. His work supports applications in packaging, biomedical materials, flexible electronics, and environmental sustainability. He combines experimental methodologies with industrial process simulation, contributing to both academic discovery and practical implementation in the field of advanced functional polymers.

Awards & Honors

Dr. Jorge Uribe-Calderon’s academic achievements are highlighted by his impact in scholarly publishing, with over 69 peer-reviewed articles, more than 1900 citations, and an h-index of 19. He is a recognized figure in polymer nanocomposite research in Latin America and has established strong collaborations with both national and international institutions. As a dedicated educator and mentor, he has supervised 8 Ph.D. theses, 7 Master’s theses, and 6 undergraduate research projects. He has also developed and taught graduate-level courses in polymer degradation, surface physicochemistry, and nanomaterials. While specific awards are not listed, his long-standing contributions to the scientific community and materials research, coupled with his leadership in training the next generation of scientists, represent his broad academic impact. His work has influenced both fundamental understanding and industrial application in polymer-based materials and nanotechnology.

Publications to Notes

Nanocrystalline cellulose (NCC) reinforced alginate based biodegradable nanocomposite film

Citations: 506

Year: 2012

Production and properties of nanocellulose-reinforced methylcellulose-based biodegradable films

Citations: 212

Year: 2010

Thermally stable phosphonium-montmorillonite organoclays

Citations: 170

Year: 2008

Conductivity variation induced by solvent swelling of an elastomer–carbon black–graphite composite

Citations: 83

Year: 1997

Influence of aramid fiber treatment and carbon nanotubes on the interfacial strength of polypropylene hierarchical composites

Citations: 80

Year: 2017

Conclusion

Dr. Jorge Uribe-Calderón exemplifies the ideal candidate for the Best Researcher Award, with a proven track record in polymer science, nanocomposites, and materials engineering. His contributions have significantly advanced understanding in bio-based and functional materials, and his dedication to academic mentorship adds to his credibility. With continued expansion into global research leadership and industry-driven innovation, his profile not only meets but exceeds the expectations for this honor

Yongwei Wang | Metallic Glasses | Best Researcher Award

Published on 22/07/202522/07/2025 by MTE Awards

Assist. Prof. Dr. Yongwei Wang | Metallic Glasses | Best Researcher Award

Assistant Professor at University of Science and Technology Beijing, China.

Dr. Yongwei Wang is a leading researcher in metallic glasses, additive manufacturing, and advanced alloy design. He currently serves as an Assistant Professor at the University of Science & Technology Beijing, within the Collaborative Innovation Center of Steel Technology. Dr. Wang has made significant contributions to the design of gradient interfaces, nanoglasses, and composition-optimized materials through data-driven and computational methods 📊💻. With a joint Ph.D. experience at the Georgia Institute of Technology , he bridges East-West academic collaboration. His research is highly interdisciplinary, integrating materials science, mechanics, and thermodynamics 🔩. A prolific author, he has published extensively in Scripta Materialia, Computational Materials Science, and MRS Bulletin 📰📚. Passionate about innovation and sustainability, Dr. Wang continues to push boundaries in developing high-strength, high-toughness materials for critical applications 🏗️.

Professional Profiles

Education📚

Dr. Wang’s academic journey began at the University of Science & Technology Beijing (USTB) 🎓, where he earned his Bachelor’s degree (2005–2009), followed by a Graduate Diploma (2009–2010), and subsequently a Ph.D. in Mechanical Engineering (2010–2017) 🧠⚙️. From 2012 to 2014, he undertook a prestigious joint Ph.D. at Georgia Institute of Technology 🇺🇸, specializing in materials science and engineering 🔬🧪. His Ph.D. research focused on the mechanical behavior of metallic glasses and the influence of microstructural heterogeneity. Through both Chinese and international platforms, he developed expertise in interface science, microstructure characterization, and computational simulations 🧬🧮. His international exposure and rigorous domestic training positioned him as a multidisciplinary thinker capable of navigating both theoretical modeling and practical engineering innovation 📘🌍. This strong foundation underpins his current research in additive manufacturing, gradient materials, and high-performance steel development 🔩🏗️.

Professional Experience

Dr. Wang currently works at the University of Science & Technology Beijing as an Assistant Professor 👨‍🏫 (2019–present), where he leads cutting-edge research in metallic glass composites, gradient nanoglasses, and structural alloy design 🔧🧱. He previously served as a Postdoctoral Fellow at Peking University (2017–2019), contributing to projects on heterogeneous microstructures and mechanical property optimization 🛠️🔬. He is deeply involved in national-level research, including China’s National Foreign Expert Project, Key R&D Plans, and several NSFC-supported studies 📊📋. His work spans advanced manufacturing, multi-level interface design, and the development of smart data standards for materials 📁🖥️. Dr. Wang also contributes as a principal investigator, co-investigator, and technical lead in multiple collaborative projects aimed at solving real-world industrial problems in metallurgy, steel processing, and high-speed transport 🚄🧪. He balances academia and engineering innovation with international collaboration and data-driven design 🧠🌐.

Research Focus 🔍

Dr. Wang’s research focuses on designing and optimizing metallic glasses, nanoglasses, and advanced high-strength materials. His projects revolve around:
1️⃣ Gradient interface strengthening to enhance both ductility and toughness
2️⃣ Oxide design and phase transformation in additive manufacturing 🔩🌡️
3️⃣ Spinodal decomposition in metallic glass composites
4️⃣ Thermodynamic modeling and experimental validation using CALPHAD and first-principles methods 🧪
5️⃣ Data standardization for materials engineering under national guidelines 📊🖥️
Dr. Wang applies a combination of experimental metallurgy, computational simulations, and data-driven design to develop materials with superior thermal stability, wear resistance, and mechanical integrity 🚀🏗️. His innovations are particularly relevant to industries such as aerospace, transportation, and high-speed rail systems 🚄🔬. Through national and international collaborations, he is redefining the future of high-performance functional materials 🌍🧬.

Awards & Honors🏆

Dr. Yongwei Wang’s research has been recognized through numerous prestigious funding programs and national research projects 🏅📘. He received the Postdoctoral Foundation for Young Scholars at Peking University and has led major grants including the National Foreign Expert Project (G2022105033L) and China’s Key R&D Plan (2020YFB0704504-02). He is a recipient of the Youth Teacher International Exchange Growth Program (QNXM20210044) and has also received internal university funds for basic research and innovation. His pioneering work on nanoglass strengthening, harmless oxide design in stainless steel, and metallic glass deformation mechanisms has not only been funded but also cited widely across global publications 📚🔍. As a leader in computational and experimental metallurgy, he continues to receive accolades for pushing boundaries in sustainable manufacturing and materials reliability ⚙️♻️. His work contributes directly to China’s goal of becoming a global leader in materials innovation.

Conclusion

Dr. Yongwei Wang exemplifies the qualities of an outstanding researcher: academic rigor, innovation, and impactful contributions to metallic glass technology, additive manufacturing, and computational alloy design. His cross-disciplinary work and leadership in national research initiatives, combined with a strong publication record, make him highly suitable for the Best Researcher Award. By increasing international visibility and expanding translational research, his profile will further solidify among top global materials scientists.

Publications to Noted

Toughen and harden metallic glass through designing statistical heterogeneity

Authors: Yongwei Wang, Mo Li, Jinwu Xu

Journal: Scripta Materialia, Vol. 113, Pages 10–13

Citations: 61

Year: 2016

Free volume gradient effect on mechanical properties of metallic glasses

Authors: Yongwei Wang, Mo Li, Jinwu Xu

Journal: Scripta Materialia, Vol. 130, Pages 12–16

Citations: 49

Year: 2017

Computational materials design: Composition optimization to develop novel Ni-based single crystal superalloys

Authors: Bin Xu, Haiqing Yin, Xu Jiang, Cong Zhang, Ruijie Zhang, Yongwei Wang, Xuanhui Qu

Journal: Computational Materials Science, Vol. 202, Article 111021

Citations: 21

Year: 2022

Mechanical properties of spinodal decomposed metallic glass composites

Authors: Yongwei Wang, Mo Li, Jinwu Xu

Journal: Scripta Materialia, Vol. 135, Pages 41–45

Citations: 16

Year: 2017

From patterning heterogeneity to nanoglass: A new approach to harden and toughen metallic glasses

Authors: Yongwei Wang, Herbert Gleiter, Mo Li

Journal: MRS Bulletin, Pages 56–67

Citations: 12

Year: 2023

Design of Ni-based turbine disc superalloys with improved yield strength using machine learning

Authors: Bin Xu, Haiqing Yin, Xu Jiang, Cong Zhang, Ruijie Zhang, Yongwei Wang, Zhi Deng, Xuanhui Qu

Journal: Journal of Materials Science, Vol. 57 (22), Pages 10379–10394

Citations: 12

Year: 2022

Manufacturing process and microstructure of copper-coated aluminum wires

Authors: Xiaohua Chen, Tang X., Zidong Wang, Hong X., Mo Li, Yongwei Wang

Journal: International Journal of Minerals, Metallurgy and Materials, Vol. 22 (2), Pages 190–196

Citations: 12

Year: 2015

Experimental investigation and thermodynamic modeling of the Mo–Co–B ternary system

Authors: Yangfan Liu, Cong Zhang, Bin Xu, Guoqiang Yang, Xue Jiang, Shuyan Zhang, Yongwei Wang, Ruijie Zhang, Haiqing Yin

Journal: Calphad, Vol. 75, Article 102354

Citations: 5

Year: 2021

Dr. Gum-Chol Jang | Nanotechnology | Best Researcher Award

Published on 19/07/202519/07/2025 by MTE Awards

Dr. Gum-Chol Jang | Nanotechnology | Best Researcher Award

Researcher at Kim Chaek University of Technology, North Korea.

Dr. Gum-Chol Jang is a dynamic researcher in the field of nanomaterials, currently serving at the Institute of Nanoscience and Nanotechnology, Kim Chaek University of Technology. 🏫 His academic journey began in 2009, and since then, he has established himself as a dedicated scientist, particularly in nanofiber development and microwave-assisted technologies. 🌐 His early fascination with material sciences matured into an intensive focus on electrospinning techniques to fabricate antibacterial nanofibers. 🧪 After obtaining his Ph.D. in Nano Materials Engineering in 2021, Dr. Jang continued to pursue innovative, real-world solutions through applied nanotechnology. His research combines experimental and computational approaches to refine electrospinning parameters, ensuring uniformity and quality in nanofiber production. ⚙️ With a commitment to sustainability, precision, and health applications, he contributes to shaping the future of nanomaterials through groundbreaking research, cross-disciplinary collaborations, and high-impact publications. 🌟 His expertise reflects a perfect blend of theoretical knowledge and technical skills. 📚

Professional Profiles

Education📚

Dr. Gum-Chol Jang embarked on his academic journey at the Faculty of Materials Science and Technology, Kim Chaek University of Technology, from 2009 to 2015. 🏫 There, he laid a strong foundation in materials science, emphasizing innovative applications and sustainable engineering. From 2015 to 2018, he pursued his Master’s degree in Nano Materials Engineering, concentrating on nanotechnology-based applications and fine-tuning electrospinning methods. 🔬 His academic excellence and research-oriented mindset led him to continue into doctoral studies at the same institution. In 2021, he earned a Doctorate in Nano Materials Engineering, specializing in nanofiber development and microwave heating techniques. 🌡️ His academic progression reflects deep immersion in material design, nanostructures, and fiber processing technologies. Dr. Jang’s strong theoretical understanding, combined with hands-on research experience throughout his academic journey, has equipped him with an exceptional skill set to lead cutting-edge advancements in nanotechnology and materials science. 🎓🔍

Professional Experience

Since 2018, Dr. Jang has been an integral part of the Institute of Nanoscience and Nanotechnology, where he has worked on high-impact projects relating to electrospinning, antibacterial nanofibers, and microwave-based material treatment. 🧫 His work focuses on optimizing the electrospinning process for consistent fiber morphology and field uniformity, enabling precise and scalable nanofiber production. 🌐 Dr. Jang’s experience bridges academic research and practical innovation, contributing to real-world solutions in disinfection, filtration, and biomedical material design. ⚙️ He has led and participated in multiple collaborative projects, refining experimental protocols and utilizing computational tools such as the Taguchi method to improve electrode configurations. 🖥️ His expertise in using microwave technology for sterilization and drying has opened new avenues for energy-efficient material processing. Through his role as a researcher, he continues to contribute valuable insights and technologies, helping to place his institute at the forefront of nanotechnology innovation. 🚀

Research Focus 🔍

Dr. Jang’s research is focused on the development of nanofibers through electrospinning technology, particularly for antibacterial and environmental applications. 🧵 His studies aim to understand and control the electrostatic forces around spinneret needles to improve fiber consistency and quality in multi-needle setups. 💡 By employing optimization methods such as the Taguchi technique, he contributes to better scalability and efficiency in nanofiber production. Additionally, he explores the use of microwave heating as an innovative approach for disinfection and drying of materials, offering energy-efficient alternatives in material processing. 🔬 His work is interdisciplinary, combining nanoscience, electrostatics, materials engineering, and applied physics. Dr. Jang’s long-term goal is to enhance material performance and sustainability in healthcare, environmental remediation, and industrial filtration. 🌍 His research not only supports theoretical advancement but also aligns with global efforts toward safer, cleaner, and more efficient technologies. 🌟

Conclusion

Dr. Gum-Chol Jang is a highly motivated and technically skilled researcher in the field of nanomaterials, particularly nanofibers and microwave applications. His work is scientifically sound and socially relevant, especially in areas like antibacterial materials and thermal treatment. While he is still in the early stages of his research career, his current contributions and academic rigor position him as a strong contender for the Best Researcher Award. With continued publishing, networking, and innovation, Dr. Jang is poised to become a leading figure in nanotechnology research.

Publications to Noted

Title: Optimization of parameters of auxiliary electrodes for electric field uniformity around spinneret needles in multi-needle electrospinning by using Taguchi method
Authors: Gum‑Chol Jang, Dong‑Chol Im, Yong‑Ho Pak
Year: 2025

Yanqing Qu | Molecular Frameworks | Best Researcher Award

Published on 18/07/202518/07/2025 by MTE Awards

Prof. Yanqing Qu | Molecular Frameworks | Best Researcher Award

Associate Professor at Qiqihar University, China.

Prof. Yanqing Qu 🎓 is an accomplished researcher and academic currently serving as a Professor at the School of Materials Science and Engineering, Qiqihar University 🇨🇳. Known for his dedication and innovation, he has made significant strides in the field of covalent organic frameworks (COFs), particularly focusing on advanced membrane materials for environmental and energy applications 🌱⚡. Despite having over 4 years in a professorial role, his impact has been profound, contributing to high-level publications and collaborations. Prof. Qu leads key projects on 2D and 3D COF membranes for applications ranging from dye separation to CO₂ capture 🌐🧪. His scientific rigor and collaborative ethos make him a respected figure among peers. Always striving to solve complex challenges through material innovation, he inspires young researchers and continues to expand the boundaries of applied materials science.

Professional Profiles

Education📚

Prof. Qu’s academic journey began with a strong foundation in polymer science and materials engineering . He pursued graduate-level education in advanced macromolecular chemistry, particularly emphasizing polymerization mechanisms and material design. During his early academic years, he gained research exposure internationally, contributing to studies on phenylacetylene polymerization and chiral materials. He received training under prominent mentors such as Prof. Aoki and Prof. Teraguchi, honing his expertise in helical polymers and functional material synthesis 🔬. His education culminated in significant publications in Chemical Letters and Polymer, reflecting both academic excellence and research capability. This diverse training in both experimental and theoretical domains has enabled him to bridge fundamental polymer chemistry with real-world applications.

Professional Experience

Prof. Qu brings a rich mix of academic and applied research experience. At Qiqihar University 🏫, he serves as a professor in the College of Materials Science and Engineering, leading advanced materials research and mentoring future scientists. He specializes in interface polymerization techniques and has developed various self-supporting polymer membranes for selective separation processes. Over the years, he has collaborated on international projects, notably working with Japanese and Chinese institutions. His hands-on experience in interfacial polymerization, microinjection, and nanostructure assembly has helped fabricate high-performance COF membranes with widespread applications including oil-water separation and gas filtration. With several impactful projects funded and published, Prof. Qu plays a pivotal role in bridging research with societal needs.

Research Focus 🔍

Prof. Qu’s research interests lie at the intersection of advanced materials chemistry and environmental engineering ⚙️. He primarily focuses on interface polymerization to create self-supporting two-dimensional covalent organic framework (COF) membranes for small molecule separation 🧪🔬. His recent work has expanded to three-dimensional COFs, targeting broader applications such as lithium-sulfur batteries, antibacterial systems, and carbon capture ♻️🔋. His approach includes using microheating, substrate alignment, and salt introduction to manipulate polymer growth in controlled environments, leading to highly permeable and selective membrane materials. He also investigates photocatalytic composites like MXene/3D-S-COF to enhance oil-water separation under visible light. Prof. Qu’s research embodies innovation with practical sustainability, pushing the boundaries of nanostructured membranes and their performance in real-world challenges.

Awards and Honors🏆

Prof. Yanqing Qu has garnered multiple accolades for his impactful contributions in polymer membrane development 🔬. His research outputs have been consistently recognized in journals of high repute such as ACS Materials Letters, Scientific Reports, and Separation and Purification Technology 📈📚. Though relatively early in his professorial journey, his groundbreaking achievements in 2D and 3D covalent organic frameworks have earned him local and regional recognition in the field of sustainable materials innovation . He has been invited to review scholarly articles and serve as a session chair in national conferences, reflecting his growing influence in the scientific community. The precision and originality of his membrane synthesis strategies place him on a trajectory for further prestigious honors, fellowships, and international research awards in the years to come.

Conclusion

Prof. Yanqing Qu is a highly suitable candidate for the Best Researcher Award. His deep expertise in advanced COF materials, consistent publication record, and meaningful contributions to environmental and energy-related challenges underscore his value as a modern materials scientist. With ongoing commitment to interdisciplinary innovation and sustainability, Prof. Qu embodies the spirit of scientific excellence and societal impact that the award seeks to recognize.

Publications to Noted

Facile fabrication of chlorine resistance Amd/TA-PVA/Amn COF composite membrane via multi-interfacial polymerization toward dye sieving

Authors: Xiaoyu Du, Tong Gu, Jingyu Xu, Yanqing Qu, Hongge Jia, Shuangping Xu, Mingyu Zhang, Jun Chen

Year: 2025

Citations: 17

Revisiting the efficacy of COF treatment for dyes in wastewater: A comprehensive review

Authors: Xiaoyu Du, Hailiang Nie, Yanqing Qu, Hongge Jia, Yang Liu, Bohan Yin

Year: 2025

Citations: 3

Photocatalytic and fouling resistant MXene/3D-S-COF for efficient oil-water emulsion separation

Authors: Yanqing Qu, Yang Liu, Xiaoyu Du, Hongge Jia, Shuangping Xu, Mingyu Zhang, Bingyang Liu

Year: 2025

Citations: 16

Soluble Imide-Bridged Polypentamethyltrisiloxane (IBPPMS) with Rationally Designed Ladder-like Structure for O2/N2 Permselectivity

Authors: Wenwen Zhao, Wenqiang Ma, Shuangping Xu, Xintian Wang, Hongge Jia, Jingyu Xu, Mingyu Zhang, Yanqing Qu, Jiao Liu

Year: 2022

Interfacial Polymerization of Self-Standing Covalent Organic Framework Membranes at Alkane/Ionic Liquid Interfaces for Dye Separation

Authors: Yanqing Qu, Yuxin Zha, Xiaoyu Du, Shuangping Xu, Mingyu Zhang, Liang Xu, Hongge Jia

Year: 2022

Xiaopeng Zhang | Flue gas | Best Researcher Award

Published on 16/07/202516/07/2025 by MTE Awards

Assoc. Prof. Dr. Xiaopeng Zhang | Flue gas | Best Researcher Award

Associate Professor at Dalian University of Technology, China.

Dr. Xiaopeng Zhang is an accomplished Associate Professor at the Dalian University of Technology, Panjin Campus 🏫. He has built an impressive academic and research career in the field of environmental catalysis and heterogeneous catalysis 🧪. With a strong focus on advanced catalytic materials, Dr. Zhang has worked on various national and provincial projects, particularly on mercury removal from flue gas using novel Co₃O₄-based and MOF-supported catalysts 🌫️. His research bridges material chemistry and environmental protection, aiming to reduce hazardous emissions from industrial sources. He is a dedicated scholar, mentor, and innovator, contributing over a dozen SCI-indexed publications 📚 and collaborating with top researchers like Junjiang Bao and Gaohong He. Dr. Zhang is committed to solving real-world pollution problems through innovative catalyst design and surface engineering ⚛️.

Professional Profiles

Education📚

Dr. Xiaopeng Zhang’s academic journey began with a Bachelor’s degree (2003–2007) from Marine College, Shandong University 🌊, followed by a Master’s degree (2007–2010) at the Center of Ecology Research, Chinese Academy of Sciences 🔬. He then pursued his Ph.D. (2010–2013) in Environmental Science and Engineering at Nankai University 🏛️. His educational background is rooted in interdisciplinary training, covering marine science, ecology, and environmental chemistry 🌱. This solid academic foundation equipped him with the theoretical and practical skills needed to explore advanced catalytic processes and the development of environmental technologies. His exposure to diverse scientific environments at three prestigious Chinese institutions has allowed him to develop a broad and integrative research outlook 📘, particularly in mercury capture, catalytic oxidation, and material synthesis.

Professional Experience

Dr. Zhang began his professional career as a Lecturer (2013–2017) at the School of Chemical Engineering, Dalian University of Technology (DUT), Panjin Campus 🏫. In 2017, he was promoted to Associate Professor, where he continues to lead research on environmental catalysts and flue gas purification. He teaches and supervises both undergraduate and postgraduate students 👨‍🏫 while conducting high-impact research in heterogeneous catalysis, focusing on pollutants like elemental mercury (Hg⁰). Over the years, he has secured multiple national-level grants and has built a robust research group focusing on surface engineering of nanomaterials. Dr. Zhang collaborates extensively with scholars across China and contributes regularly to high-impact journals 🧪📈. His professional trajectory reflects a strong commitment to research, teaching, and societal impact, particularly in the clean energy and environmental sectors.

Research Focus 🔍

Dr. Zhang’s research focuses on advanced catalytic materials for environmental applications 🔬🌍. His work centers on heterogeneous catalysis, particularly targeting the removal of elemental mercury (Hg⁰) from coal-fired flue gas using innovative Co₃O₄, MOF-based, and metal oxide catalysts ⚗️. He explores surface oxygen vacancies, crystal facet engineering, and single-atom catalysts to enhance catalytic efficiency under real-world conditions 🔥. His funded projects include developing Mn/Co-Ce-Zr catalysts and studying low-temperature SCR (Selective Catalytic Reduction) techniques to improve flue gas treatment processes. These efforts aim to minimize mercury emissions, addressing a critical environmental and public health challenge 🚫☣️. Dr. Zhang integrates experimental techniques with nanoscale material design to achieve green chemistry solutions, aligning his work with national pollution control strategies. His interdisciplinary approach combines materials science, surface chemistry, and environmental engineering to deliver practical outcomes.

Awards and Honors🏆

While formal awards are not listed, Dr. Xiaopeng Zhang has made significant contributions to environmental catalysis through his nationally funded research projects 🥇. He has received over 1 million RMB in competitive grants, including support from the National Natural Science Foundation of China and the Liaoning Provincial Natural Science Fund 💰. These recognitions affirm the scientific merit of his work on Co₃O₄ catalysts and their role in mercury removal from coal-fired power plants. His inclusion in collaborative projects with senior researchers like Junjiang Bao and Gaohong He highlights the esteem in which he is held in the research community 🤝. His contributions to multiple SCI-indexed journals and invitations to present findings further demonstrate academic recognition 🌟. As his career advances, Dr. Zhang is poised to receive formal honors for his impactful environmental research and technological innovations.

Conclusion

Dr. Xiaopeng Zhang is a highly qualified candidate for the Best Researcher Award, demonstrating a robust research portfolio with consistent publication, funded research leadership, and valuable contributions to environmental materials and catalysis. His work aligns closely with global sustainability goals and the advancement of clean energy technologies. While there is room for improvement in terms of international visibility and innovation outreach, his technical excellence, productivity, and research significance make him exceptionally suitable for this award.

Publications to Noted

Title: A comparative study of Mn/CeO₂, Mn/ZrO₂ and Mn/Ce-ZrO₂ for low temperature selective catalytic reduction of NO with NH₃ in the presence of SO₂ and H₂O
Authors: B. Shen, X. Zhang, H. Ma, Y. Yao, T. Liu
Citations: 164
Year: 2013

Title: Triple-Layered Carbon-SiO₂ Composite Membrane for High Energy Density and Long Cycling Li–S Batteries
Authors: W. Kou, X. Li, Y. Liu, X. Zhang, S. Yang, X. Jiang, G. He, Y. Dai, W. Zheng, G. Yu
Citations: 98
Year: 2019

Title: Co₃O₄ Nanosheets Preferentially Growing (220) Facet with a Large Amount of Surface Chemisorbed Oxygen for Efficient Oxidation of Elemental Mercury
Authors: H. Zhu, X. Song, X. Han, X. Zhang, J. Bao, N. Zhang, G. He
Citations: 88
Year: 2020

Title: Comparative study of liquefied natural gas (LNG) cold energy power generation systems in series and parallel
Authors: J. Bao, T. Yuan, L. Zhang, N. Zhang, X. Zhang, G. He
Citations: 87
Year: 2019

Title: Low temperature NH₃–SCR over Zr and Ce pillared clay based catalysts
Authors: S. Boxiong, M. Hongqing, H. Chuan, Z. Xiaopeng
Citations: 75
Year: 2014

Title: Reduction of efficiency penalty for a natural gas combined cycle power plant with post-combustion CO₂ capture: Integration of liquid natural gas cold energy
Authors: J. Bao, L. Zhang, C. Song, N. Zhang, M. Guo, X. Zhang
Citations: 74
Year: 2019

Title: Effect of hydrogen-bonding interaction on the arrangement and dynamics of water confined in a polyamide membrane: A molecular dynamics simulation
Authors: N. Zhang, S. Chen, B. Yang, J. Huo, X. Zhang, J. Bao, X. Ruan, G. He
Citations: 74
Year: 2018

Title: Alkali metal deactivation of Mn–CeOx/Zr-delaminated-clay for the low-temperature selective catalytic reduction of NOx with NH₃
Authors: S. Boxiong, Y. Yan, C. Jianhong, Z. Xiaopeng
Citations: 67
Year: 2013

Title: Simultaneous optimization of system structure and working fluid for the three-stage condensation Rankine cycle utilizing LNG cold energy
Authors: J. Bao, R. Zhang, Y. Lin, N. Zhang, X. Zhang, G. He
Citations: 59
Year: 2018

Title: Understanding of imidazolium group hydration and polymer structure for hydroxide anion conduction in hydrated imidazolium-g-PPO membrane by molecular dynamics simulations
Authors: N. Zhang, J. Huo, B. Yang, X. Ruan, X. Zhang, J. Bao, W. Qi, G. He
Citations: 54
Year: 2018

Yan Zhu | Image processing | Best Researcher Award

Published on 16/07/202516/07/2025 by MTE Awards

Mrs. Yan Zhu | Image processing | Best Researcher Award

Assistant at Longdong University, China.

Zhu Yan 🎓 is an Assistant at Longdong University, Qingyang, China. With a Master’s degree from Northwest Normal University, her academic foundation is rooted in Modern Educational Technology 💻. Her passion lies in image processing and computer simulation in materials science, where she explores innovative techniques for visualizing and analyzing material data. Zhu Yan’s expertise in digital image processing algorithms and data visualization 📊 has enabled her to contribute to key research projects focusing on beryllium, a potential material for nuclear fusion 🔬. She collaborates with institutions such as the Advanced Energy Science and Technology Guangdong Laboratory, bringing together experimental and computational methods for better material analysis. Committed to research and education, she strives to bridge technology and materials science in novel ways. Despite her early career status, she continues to make meaningful contributions to the scientific community 🌟.

Professional Profiles

Education📚

Zhu Yan completed her Master’s degree 🎓 from Northwest Normal University, China 🇨🇳, majoring in Modern Educational Technology 💡. Her educational background combines a strong foundation in computer science 🖥️ and material science 🔍. During her academic journey, she focused on image processing, simulation modeling, and data visualization, especially within materials research contexts. Her studies equipped her with critical thinking, software proficiency, and analytical skills, allowing her to explore interdisciplinary research 📐📊. Her educational foundation laid the groundwork for her current research on impurity behaviors in beryllium, a material of interest in nuclear fusion 🔋. Her collaboration with top institutions such as the Advanced Energy Science and Technology Guangdong Laboratory further enriched her learning through exposure to experimental and theoretical tools 🧪🔬. Zhu Yan’s academic journey reflects a blend of education and innovation tailored toward advancing material simulation and visualization.

Professional Experience

Zhu Yan currently serves as an Assistant at Longdong University 🏛️. With a specialized focus on image processing and computer simulations, she has actively participated in material science research projects. Her work includes both theoretical studies and computational modeling of materials, especially involving beryllium—a key component for nuclear fusion applications ⚛️. Zhu Yan’s responsibilities include developing digital imaging algorithms, analyzing experimental data, and creating visualizations for scientific publications. Despite being early in her career, she has shown a commitment to interdisciplinary research and has worked collaboratively with institutions such as Northwest Normal University and Advanced Energy Science and Technology Guangdong Laboratory. Her academic role blends research and educational support, fostering both student learning and scientific advancement. Her involvement in simulation-driven analysis of impurities in beryllium reflects her growing expertise in applying computational tools to material behavior studies.

Research Focus 🔍

Zhu Yan’s research centers on image processing 🖼️, materials simulation 🧪, and educational technology in material science 🎓. Her core interest lies in visual analysis and computational modeling of materials—specifically, how impurities behave within beryllium, a potential candidate for use in nuclear fusion reactors ⚛️. Her recent project combines first-principles calculations with experimental techniques to study the solution and segregation of nonmetallic (O, C, Si) and metallic (Fe, Al, Zn, etc.) impurities in beryllium. She employs digital image processing algorithms 📊 to simulate microstructural behaviors and improve the visualization of simulation results. These techniques enhance the accuracy of predictions and facilitate the manufacturing of advanced materials, such as beryllium pebbles used in fusion systems. Through interdisciplinary collaboration and algorithm development, her research aims to optimize the performance and purity of critical engineering materials 🔧🌐.

Awards and Honors🏆

As of 2025, Zhu Yan has not yet received formal awards or honors 🏅, but her impactful work and contributions in the field of materials science simulation and education technology have positioned her as a promising researcher 💫. Her publication in the Computational Materials Science journal and collaboration with prestigious Chinese research institutions reflect peer recognition and academic merit 📖. While awards may still be forthcoming, her research contributions—especially the detailed analysis of impurity behaviors in beryllium—are notable in advancing the understanding of nuclear materials 🔋. Her role in bridging computational tools and material experiments has not gone unnoticed within her academic circle. With continued dedication and outputs, Zhu Yan is on a clear trajectory toward future recognition for her contributions to materials modeling, image analysis, and educational technology 🌟.

Conclusion

While Assistant Zhu Yan is at an early career stage, her research demonstrates high relevance and promise—particularly in computational analysis of nuclear materials. Her work’s scientific merit and potential societal impact align with the vision of the Best Researcher Award. With continued publications, enhanced academic visibility, and participation in professional forums, she can emerge as a strong future leader in her field.

Publications to Noted

Title: Solution and segregation behaviors of impurity atoms in beryllium by experimental and theoretical investigations

Journal: Computational Materials Science

Publication Date: June 22, 2025 sciencedirect.com+7sciencedirect.com+7researchgate.net+7researchgate.net

Author(s): Yan Zhu (also credited as Zhu, J. K. Tian, Y. W. Liu, Z. C. Meng)

Year: 2025

Azam Anaraki Firooz | chemistry | Women Researcher Award

Published on 14/07/202514/07/2025 by MTE Awards

Assoc. Prof. Dr. Azam Anaraki Firooz | chemistry
| Women Researcher Award

Associate Prof. at Shahid Rajaee Teacher Training University, Iran.

Dr. Azam Anaraki Firooz is an Associate Professor of Inorganic Chemistry at Shahid Rajaee Teacher Training University, Tehran, Iran. She specializes in nanochemistry, catalysis, and advanced functional materials. Her prolific academic career includes impactful publications in high-ranking journals such as Applied Catalysis B: Environmental, with an h-index of 18. Dr. Firooz has led research on heterogeneous catalysis, photocatalysis, gas sensors, and fuel cell technologies. A skilled experimentalist, she utilizes advanced synthesis (sol-gel, hydrothermal) and characterization techniques (XRD, TEM, BET, DR-UV/Vis). She has fostered international collaborations and mentored over 30 students. Her work contributes significantly to sustainable energy and environmental remediation solutions. With over a decade of experience, she is recognized for innovation, scientific leadership, and cross-disciplinary teamwork.

Professional Profiles

Google Scholar

Education📚

Dr. Firooz completed her Ph.D. in Inorganic Chemistry through a joint program between the University of Tehran and Tarbiat Modares University. Her doctoral research focused on the catalytic and sensing functions of SnO₂ nanostructures, where she ranked in the top 1% of her class. She also pursued a sabbatical at Nagasaki University in Japan, synthesizing mesoporous MoO₃ nanostructures via spray pyrolysis for gas sensing. She earned her M.Sc. from Tarbiat Modares University, working on the synthesis and characterization of N-carbonyl phospho compounds. Her education combined theoretical rigor with hands-on experimental expertise in material synthesis and characterization, forming the basis of her future research in smart catalysts, functional nanomaterials, and energy/environmental applications.

Professional Experience

Dr. Azam Anaraki Firooz has over a decade of academic and research experience. She serves as Associate Professor at Shahid Rajaee University, where she has also held the position of department head for six years. She has taught undergraduate and graduate courses in inorganic chemistry and supervised over 30 theses. As a visiting professor at the University of Twente (Netherlands), she designed and synthesized smart catalysts and collaborated on advanced research projects. She has led numerous experimental studies involving catalyst development, material characterization, and sensor design. Her leadership in research, teaching, and international collaboration highlights her ability to integrate academic excellence with impactful scientific contributions in the fields of energy and environmental science.

Research Focus 🔍

Dr. Firooz’s research focuses on the synthesis and characterization of advanced inorganic and nanostructured materials for applications in catalysis, environmental remediation, and sustainable energy. She designs smart catalysts and functional materials using methods like sol-gel and hydrothermal synthesis. Her work targets heterogeneous and photocatalytic reactions for water purification and gas pollutant breakdown. She also develops gas sensors, fuel cell components, and polymer-graphite hybrid materials. Her lab is equipped with advanced tools such as XRD, TEM, BET, and DR-UV/Vis for material analysis. A key area of her interest is the interface of nanochemistry with energy conversion and sensing technologies, striving to solve environmental challenges through innovative, scalable, and environmentally friendly materials.

Awards and Honors🏆

Dr. Firooz has consistently demonstrated excellence throughout her academic journey. She graduated in the top 1% of her Ph.D. class and was selected for a prestigious research sabbatical at Nagasaki University in Japan. She has published extensively in high-impact journals such as Applied Catalysis B, receiving strong citation metrics (h-index 18) that reflect the influence of her work. Her role as head of the chemistry department and visiting professor at international institutions like the University of Twente also attest to her leadership and recognition. While specific award titles are not mentioned, her accolades include competitive research fellowships, institutional leadership positions, and invitations to collaborate globally—all of which reinforce her standing as a distinguished and award-worthy researcher.

Conclusion

Dr. Azam Anaraki Firooz is a highly deserving candidate for the Women Researcher Award. Her research in inorganic and nanochemistry, backed by a solid publication record and international experience, reflects both depth and innovation. She has contributed significantly to environmental sustainability through catalysis and sensor development. While she could benefit from greater commercialization and global stage presence, her academic leadership, mentoring impact, and scientific excellence make her a standout in her field. This award would not only recognize her current achievements but also empower her future endeavors in advancing science and mentoring the next generation of women in STEM.

Publications to Noted

🌿 Green in situ synthesis of sandwich-like W-bridged siligraphene (g-SiC@WC@g-SiC) heterostructure from Saccharum Ravennae gum for ultrahigh-rate photodegradation of acetaminophen
🗓️ Year: 2024 | 🔍 Cited by: — | 🌞 Photodegradation | 🍃 Green Chemistry | 🧪 Nanomaterials

⚡ Achievement of an efficient oxygen reduction electrocatalyst based on carbon boosted with MnOx/MnCo₂O₄ with excellent electrocatalytic activity in neutral media
🗓️ Year: 2024 | 🔍 Cited by: 2 | 🔋 Electrocatalysis | 🌐 ORR | 🧪 Carbon-Based Materials

🧬 Synthesis of Ag and Mn/ZnO nanoparticles using a hydrothermal method – A brief study and their role in the electrocatalytic oxidation of glucose in alkaline media
🗓️ Year: 2023 | 🔍 Cited by: 12 | 🧫 Nanoparticles | 💉 Glucose Sensing | ⚗️ Hydrothermal Synthesis

🧠 Green Synthesis of Nonprecious Metal-Doped Copper Hydroxide Nanoparticles for Construction of a Dopamine Sensor
🗓️ Year: 2021 | 🔍 Cited by: 14 | 🌿 Green Synthesis | 🧠 Dopamine Detection | 🔬 Biomedical Sensor

🔷 High electrochemical detection of dopamine based on Cu-doped single-phase hexagonally ZnO plates
🗓️ Year: 2021 | 🔍 Cited by: — | ⚡ Electrochemical Sensor | 🔵 ZnO Nanoplates | 🧪 Metal Doping

☀️ The Effect of Different Dopants (Cr, Mn, Fe, Co, Cu, and Ni) on Photocatalytic Properties of ZnO Nanostructures
🗓️ Year: 2020 | 🔍 Cited by: — | 🧪 Photocatalysis | 🔧 Doping Effect | 🌱 Environmental Nanoscience

Xiansheng Tang | Trnsport phenomena | Best Researcher Award

Published on 14/07/202514/07/2025 by MTE Awards

Dr. Xiansheng Tang | Transport phenomena | Best Researcher Award

Assistant Researcher at Qilu University of Technology, China.

Dr. Xiansheng Tang 🎓 is a dynamic young scientist specializing in semiconductor optoelectronic devices 💡🔬. He currently serves as an Assistant Researcher at the Laser Research Institute of Qilu University of Technology 🏫. A graduate of the prestigious University of Chinese Academy of Sciences🏅, Dr. Tang’s work revolves around flexible LEDs, GaN-based HEMTs, and light-extraction technologies📡. His studies on photogenerated carrier transport, VCSEL growth, and MBE-based material synthesis have led to breakthroughs in device efficiency and flexibility 🚀📈. With over a decade of academic and applied research experience, he has authored several high-impact papers in IEEE Photonics Journal, Optics Express, and Nanotechnology 📚. Dr. Tang’s passion for discovery and materials innovation continues to drive him toward new horizons in green energy, advanced LEDs, and next-gen photonic systems 🌍✨.

Professional Profiles

Education📚

Dr. Tang’s academic journey began at Shandong University 🎓 (2012–2016), where he earned his Bachelor of Science in physics ⚛️. He then advanced to pursue his Doctor of Science at the University of Chinese Academy of Sciences 🏅 (2016–2021), affiliated with the Institute of Physics, Chinese Academy of Sciences 🏛️. During his Ph.D., he worked extensively on epitaxial growth, light-extraction structures, and quantum well transport 🔍🧬. His doctoral training laid a robust foundation in photonic materials, optoelectronic simulation, and semiconductor device physics ⚙️📐. Throughout his academic tenure, he combined rigorous theoretical knowledge with hands-on cleanroom and lab experience 🧪🔧. His multidisciplinary education bridged physics, material science, and engineering, equipping him with powerful tools for device innovation and advanced research 📊💡. Dr. Tang’s educational background continues to shape his scientific contributions to flexible LED technology and solar energy harvesting ⚡.

Professional Experience

Since September 2021, Dr. Tang has served as an Assistant Researcher 🧑‍🔬 at the Laser Research Institute, Qilu University of Technology (Shandong Academy of Sciences) 🏢. His work spans R&D in LED technologies, including flexible AlGaInP-based red LEDs, GaN-based blue-green LEDs, and VCSEL fabrication 💡🔬. He has led and participated in key projects involving solar cell efficiency optimization, quantum well modeling, and MBE growth techniques 🌐⚗️. Dr. Tang has also contributed to the design and simulation of carrier transport behavior within advanced semiconductor junctions ⚡📊. His interdisciplinary collaboration efforts and in-lab fabrication techniques have enabled practical breakthroughs in flexible optoelectronic devices 🧪🔋. His commitment to both theoretical exploration and hands-on innovation positions him as a rising expert in next-generation photonic and energy systems 🚀. Through his academic-industrial partnerships, he continues to advance sustainable solutions and cutting-edge device development 🔍🌿.

Research Focus 🔍

Dr. Tang’s research focuses on semiconductor optoelectronic devices, with emphasis on LEDs, solar cells, and quantum well physics 💡⚛️. His main projects involve:
1️⃣ Flexible AlGaInP/GaN-based LEDs for next-gen displays and wearables
2️⃣ VCSEL fabrication and performance enhancement
3️⃣ Light extraction technologies like photonic crystals and hemisphere arrays 🌈🔍
4️⃣ Carrier transport modeling in PIN and quantum well structures
5️⃣ MBE growth and low-temp processing for material optimization 🔬🧪
6️⃣ Photonic crystal application in solar energy harvesting and incident-angle optimization ☀️
Through theoretical modeling and experimental validation, Dr. Tang advances device performance and integration 📈🧠. His research has direct implications in flexible electronics, energy-efficient lighting, and sustainable solar power systems 🌿⚙️. Combining quantum optics, materials engineering, and fabrication technology, he aims to solve real-world challenges in optoelectronics 🌍🚀.

Awards and Honors🏆

While formal honors are not listed in detail, Dr. Tang’s contributions to photonics and materials science 🌟 have earned him recognition through published research in top-tier international journals 📖🏅. His work has been featured in IEEE Photonics Journal, Optics Express, Nanotechnology, and other high-impact outlets, reflecting the quality and relevance of his contributions 📈✨. His doctoral studies at the Institute of Physics, Chinese Academy of Sciences 🏛️—a top Chinese research institute—further underscore his academic distinction. As a corresponding and first author on multiple papers, he has been trusted with leading experimental design and data interpretation 🎯📊. His projects in quantum confinement, photonic crystal optimization, and flexible LED fabrication have contributed to the growing body of knowledge in optoelectronics and energy-efficient devices 💡🔬. These academic milestones position him for future awards in innovation, sustainability, and technology leadership 🥇🌍.

Conclusion

Dr. Xiansheng Tang is a strong candidate for the Best Researcher Award, particularly in the materials science and optoelectronics domain. His record of publications, innovative contributions to LED and solar technologies, and solid academic background position him well for recognition. Addressing areas like international engagement, tech transfer, and community involvement would further bolster his candidacy for future awards at a global level.

Publications to Noted

Study on the Quantum Confinement of Photo-Generated Carriers in Quantum Wells
- Authors: Ding Ding; Weiye Liu; Jiaping Guo; Xinhui Tan; Wei Zhang; Lili Han; Zhaowei Wang; Weihua Gong; Xiansheng Tang
- Citations: 1
- Year: 2023
Improving the Performance of Solar Cells Under Non-Perpendicular Incidence by Photonic Crystal
- Authors: Xiansheng Tang; Ziguang Ma; Wenqi Wang; Zhen Deng; Yang Jiang; Wenxin Wang; Hong Chen; Na Zhang; Kaiyun Huang; Chunhua Du; et al.
- Year: 2021
Stripping GaN/InGaN Epitaxial Films and Fabricating Vertical GaN-Based Light‑Emitting Diodes
- Authors: Xiansheng Tang; Ziguang Ma; Lili Han; Zhen Deng; Yang Jiang; Wenxin Wang; Hong Chen; Chunhua Du; Haiqiang Jia
- Year: 2021

Rui Nie | Tribology | Best Researcher Award

Published on 14/07/202514/07/2025 by MTE Awards

Assoc. Prof. Dr. Rui Nie | Tribology | Best Researcher Award

Associate Researcher at Ningbo Institute of Technology, China.

Dr. Rui Nie is a distinguished researcher at the Ningbo Institute of Technology, Beihang University, specializing in mechanical tribology and surface engineering. His work addresses the pressing challenges in aerospace actuation systems and spacecraft interfaces. Through interdisciplinary approaches, Dr. Nie has significantly advanced understanding of friction, wear, and lubrication behaviors in high-performance environments. He has contributed to projects like the “973 Program” and the Chang’e lunar missions. With deep insight into ultrasonic motors, piston pumps, and tribological systems, Dr. Nie has developed dynamic models, predictive algorithms, and innovative surface treatments. His contributions extend from theory to real-world application, exemplified by his involvement in multiple prototype generations of aerospace electro-hydraulic actuation systems. His collaborative research has been published in high-impact journals and recognized through competitive funding from major national foundations. A dynamic contributor to China’s cutting-edge aerospace innovation, Dr. Nie remains committed to pushing boundaries in tribology and material performance.

Professional Profiles