Song Ziwei | Catalysis | Research Excellence Award

Published on by Analytical Chemistry

Assoc. Prof. Dr. Song Ziwei | Catalysis | Research Excellence Award

Yanshan University | China

Ziwei Song is an Associate Professor of Chemical Engineering at Yanshan University, specializing in catalysis, reaction engineering, and sustainable chemical processes. His research focuses on designing advanced catalytic materials, including bimetallic nanostructures and metal–organic frameworks, for biomass valorization, CO₂ conversion, and electrochemical energy coupling. As an independent principal investigator, he has led national and provincial projects on HMF oxidation, water electrolysis, and environmental remediation. His work integrates kinetic modeling, mechanistic insights, and process optimization, with publications in leading international journals.

Citation Metrics (Scopus)

 300
 200
 100
   20
     0

Citations
268

Documents
11

h-index
9

Citations

Documents

h-index

View Scopus Profile View ORCID Profile

Featured Publications

Jinxiao Li | Inorganic Chemistry | Best Researcher Award

Published on by Analytical Chemistry

Dr. Jinxiao Li | Inorganic Chemistry | Best Researcher Award

Dalian University | China

Dr. Jinxiao Li, currently affiliated with the College of Environmental and Chemical Engineering, Dalian University, is an accomplished researcher specializing in biomass-derived energy materials and sustainable energy conversion technologies. He earned his Ph.D. in Power Engineering and Engineering Thermophysics from Shandong University, where his doctoral research focused on the preparation of hierarchical porous carbon from plant-based materials and its application in supercapacitors. Over the past decade, Dr. Li has developed a robust research profile that bridges materials chemistry, renewable energy, and catalysis. Dr. Li’s research centers on biomass conversion, porous carbon fabrication, catalyst design, and hydrogen production. His innovative work on nitrogen-doped hierarchical porous carbons and activation techniques for improved electrochemical performance has significantly contributed to the development of high-efficiency supercapacitors and electrocatalytic systems. By integrating green synthesis methods and advanced characterization techniques such as BET, SEM-EDS, TEM, XRD, XPS, ICP, and FTIR, Dr. Li has advanced understanding of the structural-performance relationships in energy materials. With 21 publications, an impressive 1,291 citations, and an h-index of 14 (Scopus), Dr. Li’s scholarly output reflects both quality and influence in the field of energy materials and environmental chemistry. His work not only addresses fundamental scientific challenges but also offers practical implications for clean energy generation and carbon neutrality initiatives. In recognition of his research excellence, Dr. Li has been honored with the Dalian City Young Talents Award and the Outstanding College Graduates of Shandong Province Award. As an active expert member of the Dalian Energy Conservation Association, he continues to promote sustainable development through research and academic service. Dr. Li’s ongoing projects focus on next-generation biomass-based catalysts and hydrogen energy systems, positioning him as a leading figure in the pursuit of sustainable, high-performance energy materials.

Profiles : Scopus | ORCID

Featured Publications

  • Lian, M., Han, X., Li, J., Song, R., Yang, C., Zhang, J., Zhong, H., & Pan, L. (2025). Hierarchical porous carbon supports: Construction, mechanism, and catalytic performance as efficient microreactors for methanol steam reforming. Inorganic Chemistry Communications, 182(Part 2), 115561.

  • Zhao, Y.-e., Li, J., Xu, A., Liu, Y., Lian, M., Zhang, J., Zhong, H., Yang, C., Song, R., & Pan, L. (2025). Hierarchical porous carbon-supported bimetallic catalyst for enhanced low-temperature steam methane reforming. Catalysis Science & Technology.

  • Lv, S., Lian, S., Li, J., Wang, Y., Wei, J., Zhong, H., & Pan, L. (2025). Mechanochemical construction of stable Cu/MCM-41 with efficient hydrogen production via methanol steam reforming. International Journal of Hydrogen Energy, 164, 150818.

  • Li, J., Han, K., & Li, S. (2018). Porous carbons from Sargassum muticum prepared by H3PO4 and KOH activation for supercapacitors. Journal of Materials Science: Materials in Electronics.

Myrtil Kahn | Coordination Chemistry | Best Researcher Award

Published on by Analytical Chemistry

Dr. Myrtil Kahn | Coordination Chemistry | Best Researcher Award

CNRS | France

Profiles

Scopus
Orcid

Early Academic Pursuits

Dr. Myrtil L. Kahn began her academic journey with a PhD in molecular compounds, under the supervision of a renowned expert in the field of coordination chemistry. Her doctoral work laid a strong foundation in molecular chemistry, which she later expanded into interdisciplinary domains. Her postdoctoral research included advanced work on ferrite nanoparticles and intermetallic particles, which positioned her at the intersection of nanoscience, materials chemistry, and applied physics.

Professional Endeavors

Following her postdoctoral experience, Dr. Kahn joined CNRS and quickly rose through the ranks to become a Senior Scientist and Research Director. She currently leads the “Nano-chemistry, Organization, and Sensors” team at the Laboratory of Coordination Chemistry (LCC) and also co-directs a multidisciplinary research initiative in collaboration with another leading national laboratory. This joint effort culminated in the establishment of a CNRS-affiliated joint research laboratory, reflecting her leadership in managing strategic partnerships with key industrial and governmental stakeholders, including aerospace and space agencies.

Contributions and Research Focus

Dr. Kahn’s research centers on nanoscience and its application to broad societal challenges such as energy, environment, space, aeronautics, and health. She has significantly contributed to the design and synthesis of hybrid nano-objects and multifunctional coatings. Her work focuses on controlling the structural and functional properties of nanoparticles particularly semiconductor and magnetic oxides and integrating them into real-world devices. Utilizing a safe-by-design philosophy, she innovates at the interface of molecular chemistry, surface science, and nanotechnology. Her research also emphasizes understanding surface-ligand interactions through advanced techniques like NMR spectroscopy, which is crucial for ensuring colloidal stability and optimizing material behavior in biological and industrial environments.

Impact and Influence

Dr. Kahn has established herself as a leader in applied nanosciences, successfully bridging fundamental chemistry with device integration. Her research has attracted substantial funding through over thirty competitive contracts, nearly half of which involve industrial collaborations. These projects have led to multiple patents with international extensions, showcasing her commitment to innovation and knowledge transfer. Beyond scientific output, her leadership in organizing large-scale conferences and her role in interdisciplinary teams underscore her influence across both academic and industrial landscapes.

Academic Citations

Her research excellence is reflected in her strong citation metrics. With thousands of citations and an impressive h-index, her work enjoys sustained recognition in the global scientific community. She has authored more than a hundred publications in peer-reviewed international journals, contributed to several book chapters, and is actively involved in reviewing and editorial responsibilities within leading scientific events and journals.

Technical Skills

Dr. Kahn possesses deep technical expertise in organometallic synthesis, nanoparticle surface chemistry, colloidal stability, and functional coatings. She has extensive experience in spectroscopic analysis, particularly NMR, for the investigation of ligand dynamics and surface coordination. Her proficiency extends to hybrid material fabrication, integration of nanoparticles into sensors and devices, and the development of safe-by-design methodologies. This multidisciplinary toolkit enables her to work effectively at the interface of chemistry, physics, and biology.

Teaching Experience

While her primary role is research-intensive, Dr. Kahn actively contributes to mentoring young researchers and postdoctoral fellows. She fosters scientific development through collaborative research, co-authorship, and direct supervision. Her mentorship style is marked by encouraging innovation and interdisciplinary approaches, preparing early-career scientists for careers in both academia and industry.

Legacy and Future Contributions

Dr. Kahn’s legacy is one of impactful science, interdisciplinary collaboration, and societal relevance. Her commitment to applied nanoscience has led to the development of novel materials and processes with potential applications in biotechnology, aerospace, and environmental technology. As co-director of a cutting-edge joint research lab, she continues to expand her collaborative reach, ensuring that her contributions influence the next generation of researchers. Her ongoing projects in multifunctional nanocomposites and hybrid processes promise continued breakthroughs in high-performance materials.

Notable Publications

Competition between ordered morphologies of functionalized silver nanoparticles elucidated by a joint experimental and multiscale theoretical study

Authors: David Loffreda; Nathalie Tarrat; Corinne Lacaze‑Dufaure; Franck Rabilloud; Katia Fajerwerg; Myrtil L. Kahn; Vincent Collière; Christine Lepetit; Pierre Fau
Journal: Nano Today
Year: 2025

Understanding Ion‑Exchange Processes in the Synthesis of ZnSₓ@ZnO₁₋ₓ Heterostructures from Controlled Sulfidation of ZnO Nanocrystals

Authors: Ekaterina Bellan; Martin Jakoobi; Vincent Collière; Yannick Coppel; Julien Trébosc; Olivier Lafon; Pierre Lecante; Paul Fleurat‑Lessard; Céline Dupont; Jean‑Cyrille Hierso; Pierre Fau; Katia Fajerwerg; Lauriane Pautrot‑d’Alençon; Thierry Le Mercier; Myrtil L. Kahn
Journal: Chemistry of Materials
Year: 2024

Spontaneous Emulsification of Organometallic Complexes Applied to the Synthesis of Nanocapsules Active for H₂ Release from Ammonia‑Borane

Authors: Olivier Gazil; Ludivine Rault; Déborah Iglicki; Vincent Collière; Gizem Karacaoglan; Didier Poinsot; Moad Bouzid; Jean‑Cyrille Hierso; Myrtil L. Kahn; Nick Virgilio; Fabienne Gauffre
Journal: Langmuir (The ACS Journal of Surfaces and Colloids)
Year: 2024

Synthesis of TiO₂/SBA‑15 Nanocomposites by Hydrolysis of Organometallic Ti Precursors for Photocatalytic NO Abatement

Authors: Ons El Atti; Julie Hot; Katia Fajerwerg; Christian Lorber; Bénédicte Lebeau; Andrey Ryzhikov; Myrtil L. Kahn; Vincent Collière; Yannick Coppel; Nicolas Ratel‑Ramond; Philippe Ménini; Pierre Fau
Journal: Inorganics
Year: 2024

Conclusion

Dr. Myrtil L. Kahn stands as a prominent figure in nanoscience and coordination chemistry. Her pioneering research, strong industrial collaborations, and leadership in both national and international scientific communities demonstrate her eligibility for high-level scientific honors. Through her interdisciplinary vision and dedication to real-world impact, she continues to shape the future of materials science and remains an exemplary model for academic and industrial synergy.

 

Ayesha Mushtaq | Catalysis | Material Chemistry Award

Published on by Analytical Chemistry

Ms. Ayesha Mushtaq | Catalysis | Material Chemistry Award

University of Gujrat, Pakistan

👨‍🎓Profiles

🎓 Early Academic Pursuits

Ms. Ayesha Mushtaq completed her Master of Philosophy in Physics at the University of Gujrat, Pakistan, achieving an impressive CGPA of 3.72/4.0. Her thesis focused on the Investigation of MoS2 Based Nanomaterials for Efficient Photocatalytic Performance, highlighting her early dedication to advanced materials science. Prior to this, she earned her BS Honors in Physics from the University of Central Punjab. Her solid academic foundation laid the groundwork for her research in nanomaterials and their multifaceted applications.

💼 Professional Endeavors

Ms. Mushtaq has demonstrated extensive experience in synthesizing and optimizing nanomaterials, particularly focusing on MoS2, Ta-MoS2, and MoS2/MnO2/WO3 composites. Her work encompasses practical applications in photocatalysis, specifically targeting environmental remediation through degradation of dyes like Methylene Blue and pharmaceutical contaminants such as Metformin. Beyond photocatalysis, she has explored nanomaterials’ roles in energy storage, antimicrobial properties, and shelf-life extension, revealing a broad and impactful research portfolio.

📚 Contributions and Research Focus

Her research contributions extend to authoring and co-authoring scientific papers and delivering presentations in academic settings, showcasing her effective communication skills in disseminating scientific knowledge. Notably, she has authored a book titled “Influence of Nobel Metal Nanoparticles in Sustainable Energy Technologies” (Springer, 2025), emphasizing her expertise and contribution to the field of sustainable energy and nanotechnology. Her primary research interests include materials science, photocatalytic activity, energy storage, antimicrobial applications, and shelf-life enhancement using nanomaterials.

🌟 Impact and Influence

Ms. Mushtaq’s work in synthesizing novel nanomaterials and applying them to environmental and energy challenges places her at the forefront of sustainable nanotechnology research. Her scientific findings contribute not only to academic advancement but also have practical implications for environmental cleanup and energy technologies. By combining experimental research with scientific communication, she significantly influences both her academic peers and the wider scientific community.

📈 Academic Citations

While specific citation metrics are not detailed here, her published research papers and book authorship demonstrate recognition and relevance in the scientific community, particularly in nanomaterials and photocatalysis research fields.

🛠️ Technical Skills

She possesses proficiency in a range of software and instrumentation critical to materials research, including OriginLab, Xpert Highscore Plus, Image J, Endnote, MS Office, and COMSOL Multiphysics. She is skilled in operating analytical tools such as the UV-Visible Spectrometer and Photoluminescence Spectrometer for UV-Vis and PL analysis, enabling her to perform detailed characterization of nanomaterials.

👩‍🏫 Teaching Experience

Alongside her research, Ms. Mushtaq has engaged in academic research supervision, teaching, and consultation, managing theses and interdisciplinary projects. Her strong communication skills in English and Urdu facilitate effective knowledge transfer and mentorship within academic environments.

🌱 Legacy and Future Contributions

Ms. Ayesha Mushtaq is poised to continue advancing the field of nanomaterials with a focus on sustainable energy and environmental applications. Her upcoming book and ongoing research reflect a commitment to driving innovative solutions through nanotechnology, fostering interdisciplinary collaboration, and mentoring future scientists. Her legacy is set to inspire developments in photocatalytic materials, energy storage, and antimicrobial technologies, impacting both science and society.

📖Notable Publications

Photocatalytic detoxification of Lemon Yellow food additive by Novel AC@ZnO/CuO/WO3 quaternary composites via Citrus Sinensis and Solid-State-Reaction method
Authors: Hassan Imam Rizvi, Ayesha Mushtaq, Tahir Iqbal, Sumera Afsheen, Zain Ashfaq, Nabil Al-Zaqri, Ismail Warad
Journal: Journal of Alloys and Compounds
Year: 2025

Influence of Noble Metal Nanoparticles in Sustainable Energy Technologies
Authors: Tahir Iqbal, Sumera Afsheen, Ayesha Mushtaq
Book Publisher: Springer Nature Switzerland
Year: 2025
ISBN: 9783031809828, 9783031809835

Facile Strategies to Fabricate MoS2/Bi2O3 Nanocomposites; A Nano Engineered Material for Photoassisted Degradation of Ciprofloxacin and Their Antibacterial Performance
Authors: Muhammad Tauseef Qureshi, Ayesha Mushtaq, Umer Farooq, Abdul Basit, Tahir Iqbal, Ayesha Younas, Mahmoud Al Elaimi, Hira Affan, Mohamed S. Othman, Ghazala Yunus, et al.
Journal: Journal of Inorganic and Organometallic Polymers and Materials
Year: 2024

Cobalt doped MoS2: A photoactivated nanomaterial for removal of methylene blue and phenol
Authors: Tahir Iqbal, Abdul Basit, Abdallah M. Elgorban, Hind A. AL-Shwaiman, Muhammad Farooq, Muhammad Yousaf, Sumera Afsheen, Ayesha Mushtaq, Rana Mustansar Munir
Journal: Journal of Physics and Chemistry of Solids
Year: 2024

Enhancing apple shelf life: A comparative analysis of photocatalytic activity in pure and manganese-doped ZnO nanoparticles
Authors: Tahir Iqbal, Maria Afzal, Bandar Ali Al-Asbahi, Sumera Afsheen, Iqra Maryam, Ayesha Mushtaq, Sabah Kausar, Aqsa Ashraf
Journal: Materials Science in Semiconductor Processing
Year: 2024

Muthuraj Arunpandian | Catalysis | Excellence in Research Award

Published on by Analytical Chemistry

Dr. Muthuraj Arunpandian | Catalysis | Excellence in Research Award

Yeungnam University, India

👨‍🎓Profiles

👨‍🔬 Early Academic Pursuits

Dr. Muthuraj Arunpandian began his academic journey in Tamil Nadu, India, earning his Bachelor’s and Master’s degrees from Madurai Kamaraj University. He further pursued doctoral studies at Kalasalingam Academy of Research and Education, Krishnankoil, where he specialized in nanomaterials and catalysis. His academic training laid the foundation for his focused research in photocatalysis and electrocatalysis, aiming at environmental and energy-related solutions.

🌐 Professional Endeavors

Since 2023, Dr. Arunpandian has been serving as an International Research Professor at the School of Chemical Engineering, Yeungnam University, South Korea. In this role, he leads cutting-edge research in the field of catalysis, collaborating internationally to address challenges in sustainable energy and environmental remediation. His work bridges material science and chemical engineering, emphasizing interdisciplinary solutions.

🔬 Research Contributions and Focus

Dr. Arunpandian’s research is primarily focused on two interconnected areas: photocatalysis and electrocatalysis.

  • In photocatalysis, his group develops visible-light-driven semiconductor nanostructures for environmental cleanup and solar hydrogen production. Their innovations in doping strategies, heterojunction design, and surface modifications have dramatically enhanced charge carrier separation, light absorption, and overall catalytic efficiency.

  • In electrocatalysis, he pioneers low-cost, high-efficiency electrocatalysts for water splitting. His work on transition metal-based materials and single-atom catalysts has produced systems with low overpotentials, high current densities, and outstanding durability, offering scalable paths toward clean hydrogen production.

📈 Impact and Influence

Dr. Arunpandian has published over 75 research and review articles in reputed national and international journals, garnering more than 1,200 citations to date. In addition to these publications, he has contributed 2 book chapters, underlining his scholarly productivity and domain authority. His research is widely cited in areas related to green chemistry, renewable energy, and environmental remediation, reflecting its global significance.

🧪 Technical Skills and Innovations

His core technical competencies include:

  • Nanomaterial synthesis (e.g., doped semiconductors, metal-based nanostructures)

  • Photocatalytic degradation systems for pollutant removal

  • HER/OER performance optimization through material design

  • Surface/interface engineering, heterojunction fabrication, and bandgap tuning
    These skills allow him to engineer materials that are both high-performing and scalable for real-world energy and environmental applications.

🎓 Teaching and Mentorship

As an International Research Professor, Dr. Arunpandian actively contributes to academic mentoring and international research training, guiding graduate students and postdoctoral researchers in the synthesis and characterization of nanomaterials. His cross-cultural mentorship fosters innovation and scientific communication at a global scale.

🌱 Legacy and Future Directions

Dr. Arunpandian’s research contributes directly to the United Nations Sustainable Development Goals, particularly in clean energy and environmental sustainability. His future endeavors will likely focus on integrating AI-based catalyst design, scalable synthesis methods, and industry partnerships for real-world deployment. His vision is to accelerate the transition to clean hydrogen economies and pollutant-free ecosystems, leaving a lasting scientific and societal impact.

📖Notable Publications

A rational design of novel Z-scheme N-rich g-C₃N₅ supported Ag₂WO₄/BiVO₄ ternary heterojunction for remarkably enhanced visible-light-driven photocatalytic activity of acebutolol antibiotic: Performance, mechanism insight and fragments pathway analysis
Authors: Muthuraj Arunpandian, Tae Hwan Oh, Karuppaiah Selvakumar
Journal: Journal of Alloys and Compounds
Year: 2025

Exceptional Visible-Light-Driven Photodegradation Performance Over N-Rich g-C₃N₅ Decorated Flower-like SrMoO₄ Nanohybrids: Analysis of Mechanism, Efficacy and Degradation Pathway
Authors: Muralidharan S., Arunpandian M., Nagarajan E. R., Oh Tae Hwan, Selvakumar K.
Journal: Journal of Inorganic and Organometallic Polymers and Materials
Year: 2025

Fabrication of dopamine/TiO₂ nanocomposite hydrogel using fenugreek gum for efficient photocatalytic degradation of organic pollutants under visible light irradiation
Authors: Nagaraja Kasula, Arunpandian Muthuraj, Oh Tae Hwan
Journal: Journal of Industrial and Engineering Chemistry
Year: 2025

Green synthesis of Zinc Sulfide doped Ag-Zn₃(PO₄)₂ nanocomposite using bael gum: Enhanced visible-light driven photocatalytic degradation of ciprofloxacin and trypan blue with potential antimicrobial and assessment
Authors: Nagaraja Kasula, Boya Mallika, Arunpandian Muthuraj, Oh Tae Hwan
Journal: Inorganic Chemistry Communications
Year: 2025

Nitrogen-Doped Hollow Carbon Spheres-Decorated Co₂SnO₄/WS₂ Heterostructures with Improved Visible-Light Photocatalytic Degradation of Organic Dye
Authors: Muthuraj Arunpandian, Tae Hwan Oh
Journal: Molecules
Year: 2025

A facile green synthesis of manganese oxide nanoparticles using gum karaya polymer as a bioreductant for efficient photocatalytic degradation of organic dyes and antibacterial activity
Authors: Nagaraja Kasula, Muthuraj Arunpandian, Oh Tae Hwan
Journal: International Journal of Biological Macromolecules
Year: 2024

 

Liu Wenju | Catalysis | Best Researcher Award

Published on by Analytical Chemistry

Prof Liu Wenju | Catalysis | Best Researcher Award 

Henan University of Technology , china 

👨‍🎓Profiles

🎓 Early Academic Pursuits

Professor Liu Wenju embarked on his academic journey with a strong foundation in chemistry. He earned his B.Sc. in Applied Chemistry from Zhengzhou University in 2003, followed by an M.Sc. in Industrial Catalysis at the same institution, where he explored the catalytic oxidation of cooking oil fumes in microwave fields. His passion for advanced separation techniques and materials led him to pursue a Ph.D. in Chemical Engineering at Tianjin University, where he completed a groundbreaking thesis on the crystallization and polymorphism of Carbamazepine, a critical pharmaceutical compound. These early academic milestones laid the groundwork for a career dedicated to innovation in crystallization science and green chemical processes.

🧪 Professional Endeavors

Prof. Liu’s professional path is marked by impactful roles across academia and research institutions. He has served as a postdoctoral researcher at Tianjin University, leading pharmaceutical crystallization studies, and expanded his global perspective as a visiting scholar at the University of Cambridge, where he studied mechanochemical modifications of Salbutamol Sulfate. His role as a principal investigator on multiple funded research projects reflects his leadership in the field, especially within the National Natural Science Foundation of China (NNSFC).

🔬 Contributions and Research Focus

Prof. Liu has cultivated a distinguished research profile centered on chemical separation and crystallization, particularly within the pharmaceutical domain. His expertise includes industrial crystallization, polymorphism control, and green catalysis. Over the years, he has advanced critical insights into amorphization, polymorphic membrane crystallization, and impurity effects on crystal growth, aligning with sustainable chemistry goals. His research extends to eco-friendly material development, showcasing a commitment to environmentally conscious innovation.

🌍 Impact and Influence

The scope of Prof. Liu's research has significantly influenced pharmaceutical manufacturing practices and the development of greener catalytic systems. His work on crystal engineering and nucleation-growth dynamics has contributed to both academic understanding and practical applications. The international recognition gained through collaborations, such as with the University of Cambridge, highlights his role in bridging global research efforts and fostering knowledge exchange in the field of chemical engineering.

📚 Academic Citations & Scholarly Recognition

While specific citation metrics are not included, Prof. Liu's funded projects, especially by the NNSFC and other national and international bodies, signify his academic credibility and research influence. His work on pharmaceutical polymorphs, crystallization mechanisms, and green catalytic technologies continues to inspire new lines of inquiry and collaboration in chemical engineering research.

🛠️ Technical Skills

Prof. Liu brings advanced technical proficiency to his research. His core competencies include:

  • Pharmaceutical crystal engineering

  • Polymorph screening and control

  • Green catalytic process design
    He is adept with cutting-edge analytical tools such as:

  • PXRD (Powder X-ray Diffraction)

  • DSC (Differential Scanning Calorimetry)

  • SEM-EDS (Scanning Electron Microscopy – Energy Dispersive Spectroscopy)

  • HPLC-MS (High-Performance Liquid Chromatography – Mass Spectrometry)

  • In-situ Raman spectroscopy

👨‍🏫 Teaching & Mentoring Excellence

Although specific teaching roles are not detailed, Prof. Liu’s deep research involvement at Henan University of Technology suggests active engagement in mentoring graduate students and guiding thesis research, especially in crystallization and catalysis. His interdisciplinary knowledge positions him as an effective educator in both theoretical and applied chemistry fields.

🌱 Legacy and Future Contributions

Prof. Liu's early research into CO removal and microwave-assisted oxidation systems highlights a lifelong dedication to environmental sustainability. As he continues his academic journey, his future contributions are likely to deepen in the domains of eco-friendly crystallization technologies and pharmaceutical manufacturing innovations. His legacy will undoubtedly be one of bridging scientific rigor with practical environmental applications, shaping the next generation of chemical engineers.

📖Notable Publications

Title: Zr-doped CoZrOx solid solution catalysts with enhanced oxygen vacancy for trace ethylene removal under humid conditions
Authors: Zhang Qiaofei, Zhang Liwen, Liu Lei, Zhu Chunshan, Liu Wenju
Journal: Applied Surface Science
Year: 2025
Citations: 0

Title: Preparation of CunCo1Ox catalysts by co-precipitation method for catalytic oxidation of toluene
Authors: Hu Yanshao, Pan Da, Zhang Zheng, Dang Dan, Liu Wenju
Journal: Journal of Molecular Structure
Year: 2025
Citations: 0

Title: Multifunctional self-cleaning Zr-Porphyrin@PG membrane for wastewater treatment
Authors: Liu Wenju, Hou Yafang, Zhao Peixia, Zhang Yatao, D'Agostino Carmine
Journal: Applied Surface Science
Year: 2025
Citations: 0

Title: Equilibrium Solubility of Loxoprofen in 14 Monosolvents: Determination, Correlation, and Hansen Solubility Parameter
Authors: Shen Yanmin, Pan Shuting, Gao Yuqi, Wang Han, Liu Wenju
Journal: Journal of Chemical and Engineering Data
Year: 2025
Citations: 0

Zhongsheng Wang | Chemical Engineering | Best Researcher Award

Published on by Analytical Chemistry

Mr. Zhongsheng Wang | Chemical Engineering | Best Researcher Award

Central South University, China

👨‍🎓Profiles

🔬 Academic and Professional Background

Mr. Zhongsheng Wang is a Doctoral Candidate at Central South University, specializing in lithium battery electrolyte research. His academic journey has been marked by significant contributions to battery technology and regulation. His work has led to publications in high-impact journals, reflecting his dedication to advancing the field of energy storage.

⚡ Research and Innovations

Mr. Wang focuses on lithium battery electrolytes, with a particular interest in low-temperature lithium battery technology. His research explores novel strategies to improve battery performance, efficiency, and durability in extreme conditions. He has contributed to understanding battery interfacial reactions, proposing the bond-level control theory for electrode-electrolyte interfaces.

🏆 Completed/Ongoing Research Projects

His research spans various aspects of battery technology, including battery regulation techniques. As part of the Central South University Graduate Innovation Program, he has led multiple projects aimed at improving lithium battery performance in low-temperature environments.

📊 Citation Index and Contributions

Mr. Wang’s research has been recognized in the scientific community, with his work accumulating 8 citations. He has successfully analyzed battery system evolution processes and developed multiple low-temperature lithium battery systems, contributing to advancements in battery theory.

📑 Patents and Publications

Mr. Wang has published several papers in prestigious journals, including Advanced Functional Materials, Energy Material Advances, EcoMat, Journal of Alloys and Compounds, and Chemical Science. His innovative research has also resulted in two patents, further demonstrating his impact in the field.

🤝 Collaborations

Mr. Wang has collaborated with researchers on multiple studies, leading to publications in renowned journals such as Advanced Functional Materials and Colloids and Interface Chemistry in Chemical Science. These collaborations have strengthened the research and development of next-generation lithium batteries.

🔍 Areas of Research

  • Lithium Battery Electrolytes

  • Low-Temperature Lithium Battery Technology

  • Electrode-Electrolyte Interface Reactions

  • Battery Regulation Techniques

🌟 Future Contributions

Mr. Wang’s research continues to push the boundaries of battery technology, particularly in developing novel electrolyte formulations that enhance lithium battery performance at low temperatures. His work is expected to have a lasting impact on energy storage solutions, paving the way for next-generation batteries with improved efficiency and reliability.

📖Notable Publications

Bo Wu | Physical Chemistry | Best Researcher Award

Published on by Analytical Chemistry

Dr. Bo Wu | Physical Chemistry | Best Researcher Award

Institute of Chemistry, Chinese Academy of Sciences, China

👨‍🎓Profiles

🎓 Academic Background

Dr. Bo Wu received her Ph.D. degree in 2016 from the Institute of Chemistry, Chinese Academy of Sciences (CAS), China. With a strong foundation in photoelectric nanomaterials and nanochemistry, she has rapidly emerged as a leading researcher in the field of fullerene-based nanocomposites and their diverse applications.

🏅 Professional Endeavors and Leadership

Dr. Wu is currently a professor at the Institute of Chemistry, CAS, where she leads pioneering research on photoelectric properties of fullerene-based nanocomposites. As a key research backbone and project leader, she has undertaken more than 10 prestigious research projects funded by the Ministry of Science and Technology of China, the National Natural Science Foundation of China (NSFC), and the Chinese Academy of Sciences. Her innovative contributions have played a crucial role in advancing the development of nanophotonic and optoelectronic materials.

🔬 Research Contributions and Innovations

Dr. Wu’s work revolves around developing novel fullerene-based nanocomposites with enhanced photoelectric properties, aiming to optimize their applications in optoelectronics, photovoltaics, and nanophotonics. Her research has contributed significantly to the design, synthesis, and functionalization of fullerene derivatives for high-performance energy materials.

🌍 Impact and Recognition

Her outstanding contributions have been widely recognized in the scientific community. She has published more than 20 high-impact journal articles in renowned scientific journals, including Nature Communications, Journal of the American Chemical Society (JACS), and Angewandte Chemie International Edition (Angew. Chem. Int. Ed.). These publications highlight her work in nanochemistry, material science, and energy conversion technologies, solidifying her reputation as an influential researcher.

🏆 Awards and Achievements

Dr. Wu has received numerous prestigious awards and recognitions:

  • 2018: Selected as a member of the Youth Innovation Promotion Association of the Chinese Academy of Sciences, where she was recognized for her exceptional performance.

  • 2023: Awarded the Outstanding Youth Foundation grant by the National Natural Science Foundation of China (NSFC), recognizing her significant contributions to the field of photoelectric nanomaterials.

  • 2023: Honored with the Young Cutting-Edge Nanochemistry Research Award, a testament to her groundbreaking work in nanotechnology.

🛠️ Technical Expertise

Dr. Wu possesses expertise in nanomaterials synthesis, optoelectronic characterization, molecular self-assembly, organic photovoltaic devices, and photoelectric conversion technologies. Her advanced research techniques have contributed to enhancing efficiency and stability in nanocomposite-based devices.

🚀 Future Contributions and Research Vision

Dr. Wu is committed to pushing the boundaries of nanochemistry and photoelectric nanomaterials. Her future research aims to develop next-generation optoelectronic materials, high-performance organic semiconductors, and innovative nanostructured energy devices. With her visionary leadership and dedication, she continues to inspire young researchers and drive scientific advancements in the field of functional nanomaterials and energy conversion technologies.

📖Notable Publications

Photoinduced Ultrafast Multielectron Transfer and Long-Lived Charge-Accumulated State in a Fullerene-Indacenodithiophene Dumbbell Triad

Authors: Chong Wang, Bo Wu, Yang Li, Chunru Wang, Chunli Bai
Journal: Proceedings of the National Academy of Sciences of the United States of America
Year: 2024

Aggregation Promotes Charge Separation in Fullerene-Indacenodithiophene Dyad

Authors: Chong Wang, Bo Wu, Yang Li, Rui Wen, Chunru Wang
Journal: Nature Communications
Year: 2024

Natthawan Prasongthum | Catalysis | Best Researcher Award

Published on by Analytical Chemistry

Prof. Natthawan Prasongthum | Catalysis | Best Researcher Award

Khon Kaen University, Thailand

👨‍🎓Profiles

🎓 Early Academic Pursuits

Prof. Natthawan Prasongthum has a strong academic background in petrochemistry and chemistry. She graduated with First Class Honors in Chemistry (B.Sc.) from Ubonratchathani University, Thailand. She then completed her M.S. in Petrochemistry and Polymer Science (GPA 3.67) and earned a Ph.D. in Petrochemistry with a perfect GPA of 4.00 from Chulalongkorn University, Bangkok. Her early academic focus laid the groundwork for her later specialization in carbon materials and clean energy solutions.

💼 Professional Endeavors

Prof. Prasongthum is currently a Lecturer at the Faculty of Science, Khon Kaen University, where she teaches Battery Science and New Energy to undergraduate students. Prior to this, she was a dedicated Researcher at the Thailand Institute of Scientific and Technological Research (TISTR), where she focused on renewable energy, CO2 capture, carbon materials, and catalyst development. Her international experience includes serving as a Postdoctoral Fellow at the University of Regina, Canada, where she contributed to cutting-edge research on Carbon Capture, Utilization, and Storage (CCUS) technology.

🔬 Contributions and Research Focus

Prof. Prasongthum’s research is centered on advancing technologies in carbon capture and utilization (CCU), focusing on CO2 conversion and storage through innovative catalytic processes. She specializes in synthesizing heterogeneous catalysts, zeolites, and carbon-based materials for environmental and energy-related applications. Her work extends into the development of carbon materials for energy storage devices like supercapacitors and batteries, as well as sustainable fuel production methods.

🌍 Impact and Influence

With a mission to contribute to global clean energy transitions, Prof. Prasongthum is committed to addressing the challenges of climate change through carbon-neutral solutions. Her interdisciplinary expertise in material science, catalysis, and renewable energy technologies is helping shape more sustainable and circular energy systems, aligning with global net-zero carbon goals.

📚 Academic Contributions

Prof. Prasongthum has authored multiple research reports, scientific publications, and proposals related to CO2 utilization and energy storage materials. She has also been actively involved in mentoring undergraduate students, interns, and volunteers, helping to foster the next generation of researchers in the field of clean energy and advanced materials.

🧪 Technical Skills

Her technical skillset includes the design and synthesis of heterogeneous catalysts, development of carbon materials, CO2 capture and utilization technologies (CCUS), renewable energy systems, and energy storage materials. Additionally, she is proficient in data analysis, research proposal writing, and project management in R&D settings.

👩‍🏫 Teaching Experience

Currently, as a Lecturer at Khon Kaen University, Prof. Prasongthum teaches core subjects related to Battery Science and New Energy. She brings a wealth of research knowledge to the classroom, blending theoretical concepts with hands-on insights from her industry and academic research background.

🌟 Legacy and Future Contributions

Prof. Prasongthum’s future vision is to continue advancing sustainable technologies for carbon capture and energy storage. She aims to lead research projects that will pave the way for innovative CCUS technologies, novel carbon-based materials, and eco-friendly energy solutions, contributing to Thailand’s and the global community’s transition to a low-carbon economy.

📖Notable Publications

Hydrothermal synthesis of calcium methoxide nano-catalyst for palm oil based biolubricant production
Authors: L. Attanatho, A. Suemanotham, Y. Thanmongkhon, S. Kaewmala, N. Prasongthum
Journal: Molecular Catalysis
Year: 2025

High-Porosity Hydrochar From Oil Palm Empty Fruit Bunches Via Single-Step Hydrolytic Agent-Assisted Hydrothermal Carbonization
Authors: W. Sisuthog, N. Prasongthum, P. Natewong, P. Reubroycharoen
Journal: Indonesian Journal of Science and Technology
Year: 2024

Fibrous Platelet Carbon Nanofibers-Silica Fiber Composite Supports for a Co-based Catalyst in the Steam Reforming of Acetic Acid
Authors: P. Natewong, N. Prasongthum, P. Reubroycharoen
Journal: Applied Catalysis A
Year: 2018

Investigation of Ni/SiO2 Fiber Catalysts Prepared by Different Methods on Hydrogen Production from Ethanol Steam Reforming
Authors: S. Mhadmhan, P. Natewong, N. Prasongthum, C. Samart, P. Reubroycharoen
Journal: Catalysts
Year: 2018

Solvent Regeneration of a CO2-Loaded BEA-AMP Bi-blend Amine Solvent with the aid of a Solid Brønsted Ce(SO4)2/ZrO2 Super-Acid Catalyst
Authors: N. Prasongthum, P. Natewong, P. Reubroycharoen, R. Idem
Journal: Energy Fuels
Year: 2018

Synthesis of Carbon Nanotubes (CNTs) over Ni/MgO Catalyst from CH4/CO2 and its Application for CO2 Absorption in BEA-AMP Bi-solvent Blend
Authors: P. Natewong, N. Prasongthum, P. Reubroycharoen, R. Idem
Journal: CleanEnergy
Year: 2019

Evaluating the CO2 Capture Performance using a BEA-AMP Bi-blend Amine Solvent with Novel High-Performing Absorber and Desorber Catalysts in a Bench-Scale CO2 Capture Pilot Plant
Authors: P. Natewong, N. Prasongthum, P. Reubroycharoen, R. Idem
Journal: Energy Fuels
Year: 2019

Tianchao Niu | Surface Chemistry | Best Researcher Award

Published on by Analytical Chemistry

Prof. Dr. Tianchao Niu | Surface Chemistry | Best Researcher Award

Beihang University, China

👨‍🎓Profiles

Prof. Dr. Tianchao Niu is a distinguished researcher in the field of low-dimensional materials, with expertise in scanning tunneling microscopy (STM), molecular beam epitaxy (MBE), and surface/interface physicochemical properties. His research focuses on the controllable preparation of semiconductor materials and optimization of device-related interface properties, making significant contributions to nanotechnology and materials science.

🎓 Early Academic Pursuits

Dr. Niu began his academic journey at Ludong University, where he earned his Bachelor’s degree in Chemistry Education (2002-2006). He then pursued a Master’s degree (2006-2009) at Suzhou University, focusing on electrochemical and surface-enhanced Raman spectroscopy studies of ionic liquid/metal interface structures. His passion for surface science and nanomaterials led him to the National University of Singapore (2009-2013), where he obtained a Ph.D. in Physical Chemistry under the supervision of Prof. Chen Wei. His doctoral research, centered on low-temperature scanning tunneling microscopy studies of molecular dipole self-assembly on surfaces, laid the foundation for his future work in nanomaterials and interface engineering.

🏛️ Professional Endeavors

Dr. Niu has built an impressive career, holding academic and research positions in renowned institutions across China and the United States. His professional journey includes a postdoctoral fellowship (2016-2017) at the Brookhaven National Laboratory, USA, where he worked at the Center for Functional Nanotechnology. From 2013 to 2016, he was an Assistant Researcher at the Shanghai Institute of Microsystem and Information Technology, Chinese Academy of Sciences, contributing to research in superconductivity and surface science. He later joined Nanjing University of Science and Technology (2017-2020) as a Professor in the School of Materials Science and Engineering before becoming a Tenured Associate Professor at Shanghai Jiao Tong University (2020-2021). Currently, he serves as an Associate Professor at the International Innovation Institute, Beihang University (since 2021), where he continues his pioneering research on low-dimensional materials and nanotechnology.

🔬 Contributions and Research Focus

Dr. Niu’s research is centered on the growth mechanisms, characterization, and application of low-dimensional semiconductor materials. His work integrates STM characterization, chemical vapor deposition (CVD), and MBE techniques to investigate the surface and interface properties of two-dimensional (2D) materials. Additionally, he specializes in vacuum system design, interconnection, and construction, contributing to the development of high-performance nanodevices. His studies have led to advancements in next-generation electronics, optoelectronics, and quantum materials, with a strong emphasis on device optimization and novel material synthesis.

📚 Impact and Influence

As a leading scientist in materials research, Dr. Niu has authored over 40 research papers and review articles as the first or corresponding author in high-impact journals such as Journal of the American Chemical Society (JACS), Nano Today, Advanced Materials, ACS Nano, Progress in Surface Science, and 2D Materials. His publications provide groundbreaking insights into nanomaterial growth and interface engineering, influencing researchers and industries in nanoelectronics, energy storage, and advanced material applications. His high citation index reflects the significant impact of his research in the global scientific community.

🛠️ Technical Expertise

Dr. Niu has mastered a wide range of cutting-edge experimental techniques essential for nanomaterial research. His expertise includes low-temperature to high-pressure scanning tunneling microscopy (STM), X-ray photoelectron spectroscopy (XPS) for surface chemical analysis, and molecular beam epitaxy (MBE) for thin-film growth. He is also skilled in vacuum system design and integration, allowing for precise control over material fabrication processes. His technical proficiency has enabled the development of high-quality, application-oriented nanomaterials.

👨‍🏫 Teaching and Mentorship

Beyond his research, Dr. Niu is an active educator and mentor at Beihang University. He is dedicated to training the next generation of material scientists and engineers, emphasizing hands-on experimentation, interdisciplinary collaboration, and innovation in nanotechnology. He has supervised numerous doctoral and postdoctoral researchers, guiding them in advanced materials research and applications. His teaching approach bridges theoretical knowledge with real-world applications, fostering scientific curiosity and technical excellence among his students.

🚀 Legacy and Future Contributions

Dr. Niu’s future research endeavors aim to expand the capabilities of semiconductor materials for flexible electronics and quantum computing. He continues to develop novel methodologies for precise control of 2D material properties, which could lead to breakthroughs in nanoscale device performance and functionality. His vision includes strengthening global collaborations in nanoscience to accelerate technological advancements and push the boundaries of materials innovation. His pioneering work not only enhances scientific understanding but also paves the way for transformative applications in next-generation technology.

📖Notable Publications

One-dimensional topological phase and tunable soliton states in atomic nanolines on Si(001) surface
Authors: B. Song, Biyu; G. Zhi, Guoxiang; C. Hua, Chenqiang; T. Li, Tianzhao; T. Niu, Tianchao
Journal: npj Quantum Materials
Year: 2024

Epitaxial Growth of 2D Binary Phosphides
Authors: W. Gao, Wenjin; W. Dou, Wenzhen; D. Zhou, Dechun; C. Hua, Chenqiang; A.T. Wee, Andrew T.S.
Journal: Small Methods
Year: 2024

Atomically Precise Bottom-Up Fabrication of Ultra-Narrow Semiconducting Zigzag BiP Nanoribbons
Authors: D. Zhou, Dechun; Y. Feng, Yisui; L. Zhang, Lei; H. Li, Hui; T. Niu, Tianchao
Journal: Advanced Functional Materials
Year: 2024

Growth of Single Crystalline 2D Materials beyond Graphene on Non-metallic Substrates
Authors: W. Gao, Wenjin; G. Zhi, Guoxiang; T. Niu, Tianchao
Journal: Small
Year: 2024

Room-temperature magnetic higher-order topological states in two-dimensional transition metal dichalcogenides and dihalogenides
Authors: C. Hua, Chenqiang; D. Shao, Dexi; W. Wu, Weikang; T. Niu, Tianchao; S.A. Yang, Shengyuan A.
Journal: Physical Review B
Year: 2024

Anisotropic Strain-Mediated Growth of Monatomic Co Chains on Unreconstructed Regions of the Au(111) Surface
Authors: B. Song, Biyu; W. Gao, Wenjin; G. Zhi, Guoxiang; M. Wu, Meimei; T. Niu, Tianchao
Journal: Chemistry of Materials
Year: 2024