Weiqing Jiang | Physical Chemistry | Best Researcher Award

Published on by Analytical Chemistry

Prof. Dr. Weiqing Jiang | Physical Chemistry | Best Researcher Award

Guangxi University | China

Profiles

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Early Academic Pursuits

Professor Weiqing Jiang began her academic journey in the field of chemical technology, where she pursued and completed her doctoral studies. From the outset, she exhibited a strong interest in the development and optimization of materials that contribute to energy storage and conversion. Her early academic efforts laid a strong foundation in materials science, particularly in solid-state chemistry and electrochemical systems.

Professional Endeavors

Following her doctoral work, Professor Jiang took on a faculty position at Guangxi University, where she currently serves as a professor in the School of Physical Science and Technology. Her role encompasses both research and academic leadership, positioning her as a key figure in advancing the university’s materials science program. Over the course of her career, she has successfully completed multiple research projects supported by national and regional scientific foundations, affirming her ability to attract funding and execute high-level research programs.

Contributions and Research Focus

Professor Jiang’s primary research centers on solid-state hydrogen storage materials and electrode materials for nickel/metal-hydride (Ni/MH) rechargeable batteries. A distinctive feature of her work is the integration of experimental techniques with first-principles theoretical calculations, enabling her to uncover insights into hydrogenation and dehydrogenation mechanisms. Her findings have shown that annealing processes can significantly improve electrochemical performance and that the inclusion of more electronegative elements in metal hydrides enhances thermal stability, thus influencing both thermodynamic and kinetic behaviors. Her research provides valuable pathways for the development of advanced, high-performance energy storage materials.

Impact and Influence

Professor Jiang’s research has gained meaningful recognition, both nationally and internationally. Her work on La-Ti-Mg-Ni-based alloys for hydrogen storage was noted as particularly innovative and was evaluated as highly promising by an international award committee. This acknowledgement reflects the practical applicability and forward-thinking nature of her research, which aligns closely with global efforts toward clean energy and sustainable technology.

Academic Citations

With a citation index of over 300 across her publications in SCI-indexed journals, Professor Jiang’s work has established a clear academic footprint. Her citation count indicates sustained engagement from the scientific community, reflecting the relevance and utility of her contributions in the domain of hydrogen storage materials and electrochemical systems.

Technical Skills

Professor Jiang is proficient in a wide range of technical areas, including solid-state synthesis, structural and phase characterization of materials, electrochemical testing, and computational modeling through first-principles calculations. Her dual competency in experimental and theoretical approaches gives her a unique advantage in materials research, enabling her to validate experimental observations with predictive modeling.

Teaching Experience

As a professor, Professor Jiang plays a vital role in the academic development of undergraduate and graduate students. Her teaching integrates cutting-edge research with classroom instruction, enriching student learning with real-world scientific challenges. She likely supervises graduate theses and projects, contributing to the development of future researchers in the field of materials science.

Legacy and Future Contributions

Professor Jiang’s legacy lies in her methodical and innovative approach to solving fundamental problems in hydrogen storage and energy conversion. Moving forward, she is poised to make even greater contributions by expanding her research to interdisciplinary areas such as hydrogen fuel infrastructure, lightweight alloy design, and renewable energy integration. Her ongoing projects suggest a sustained commitment to the advancement of clean energy technologies.

Notable Publications

Atomic spin engineering of Fe-N-C by axial chlorine-ligand modulation for lightweight and efficient electromagnetic wave absorption

  • Authors: Qi Wei, Pan Zhang, Xinyu Guo, Weiqing Jiang, Xiaoma Tao, Pei Kang Shen, Zhi Qun Tian
    Journal: Journal of Colloid and Interface Science
    Year: 2025

Role of Fe, Co and Ni in dehydrogenation thermodynamics and kinetics of LiBH₄ (010) surface: a first-principles study

  • Authors: Yu Ma, Xiaohua Mo, Changhong Li, Jincheng Wang, Jiafang Qin, Chunxi Pang, Tian Liang, Yifan Qiu, Weiqing Jiang
    Journal: International Journal of Hydrogen Energy
    Year: 2025

Enhanced dehydrogenation of MgH₂ modified by Ti and S: A first-principles investigation

  • Authors: Xiaoli Zuo, Xiaohua Mo, Weiqi Zhou, Jinlin Zhang, Chunyan Hu, Weiqing Jiang
    Journal: International Journal of Hydrogen Energy
    Year: 2024

Dehydrogenation properties of LiBH₄ modified by Mg from first-principles calculations

  • Authors: Xiaohua Mo, Weiqing Jiang
    Journal: Journal of Alloys and Compounds
    Year: 2018

Effect of Al on the dehydrogenation of LiBH₄ from first-principles calculations

  • Authors: Jiang Weiqing, Cao Shilong
    Journal: International Journal of Hydrogen Energy
    Year: 2017

Conclusion

Professor Weiqing Jiang is a respected and impactful figure in the field of hydrogen storage materials. Her pioneering research, successful project leadership, recognized innovation, and academic contributions collectively demonstrate her significance in the global scientific community. Through continued exploration and mentorship, she is set to play a lasting role in shaping the future of sustainable energy research and materials science.

 

Davide Rossi | Physical Chemistry | Best Researcher Award

Published on by Analytical Chemistry

Dr. Davide Rossi | Physical Chemistry | Best Researcher Award

University of Padua, Italy

Profiles

Early Academic Pursuits

Dr. Davide Rossi embarked on his academic journey in the pharmaceutical sciences by completing a combined B.S. and M.D. in Pharmacy at the Department of Pharmaceutical Sciences, University of Camerino, Italy. His formative academic years laid the foundation for a multidisciplinary approach that integrates physical chemistry with pharmaceutical applications. His early interests in understanding the physicochemical behaviors of materials evolved into specialized expertise in surface tensiometry and its practical relevance in drug systems and biointerfaces.

Professional Endeavors

Dr. Rossi has been actively engaged as a Researcher Collaborator and Contractor Researcher at the Department of Pharmaceutical and Pharmacological Sciences, University of Padova, Italy. In his role, he has pioneered analytical methodologies to determine surface tension in liquids, successfully eliminating the interference of surface roughness and friction forces. His methodology culminated in a unique pure number-based approach—now recognized in surface tensiometry—which provides unprecedented precision in characterizing drug release, permeation processes, and biopharmaceutical behavior. He has also served as the Technical Director for the Osservatorio Termale Permanente (OTP), contributing significantly to studies on peloids, sanitizing technologies, and electrochemical systems in healthcare.

Contributions and Research Focus

Dr. Rossi’s most impactful scientific contributions are centered around the development of innovative concepts in surface tensiometry. These include the Solid-Like Methodology (SLM), the definition of the Rossi number—a dimensionless index to describe tensiometric behavior—and the Integrated Analytical Approach (IAA), a novel framework that merges volume element, structure, and surface data to investigate dynamic behaviors in complex systems. His work bridges theoretical surface science with tangible applications in drug release, monoclonal antibody characterization, and ex vivo permeation phenomena.

Impact and Influence

The influence of Dr. Rossi’s research extends into applied pharmacological technology, especially in the thermal, biological, and electrochemical domains. His patented developments—including the Tensiometric PFPE Liquid Film, the Surface Tensiometry PFPE Liquid Film (Rossi number), and PFPE Biological Fixative—demonstrate strong translational value, particularly in pharmaceutical testing and therapeutic material innovation. His research has sparked new standards in how tensiometry is applied in quality control, safety assessments, and the material sciences.

Technical Skills

Dr. Rossi possesses extensive expertise in analytical instrumentation and surface analysis. His specialization in surface tensiometry involves precise measurement techniques and modeling of liquid-solid interactions within complex biological and synthetic systems. His methodological advancements reveal proficiency in the use of custom-built devices and multi-parametric models to investigate structural integrity and material behavior.

Teaching Experience

Though primarily a research-focused professional, Dr. Rossi has also contributed to academic mentorship and collaborative scientific exchanges within his institution and professional networks. His involvement in research contracts and inter-institutional initiatives suggests a strong role in training early-career researchers and fostering analytical thinking in pharmaceutical sciences.

Academic Collaborations and Memberships

Dr. Rossi has cultivated international research collaborations, notably as a co-founding member of the H₂S in Balneology Global Initiative, working alongside leading figures in therapeutic hydrology. He holds membership in prestigious professional organizations including the Association of Pharmacist International (API) and the American Chemical Society (ACS), aligning his research within global scientific communities and ensuring exposure to interdisciplinary innovations.

Legacy and Future Contributions

With a focus on systematizing surface data and integrating them into pharmaceutical evaluation protocols, Dr. Rossi’s legacy is the transformation of surface tensiometry from a niche analytical tool into a cornerstone of modern pharmaceutical characterization. His ongoing research aims to refine his methodologies further for broader application across natural and artificial systems. The fusion of structural science, surface dynamics, and drug technology in his work promises to influence future drug design, delivery systems, and material validation techniques.

Notable Publications

Within-tree variations in the surface free energy of wood assessed by contact angle analysis
Authors: Rossi, Davide; Rossi, Sergio; Morin, Hubert; Bettero, Antonio
Journal: Wood Science & Technology
Year: 2012

A combined chemico-mineralogical and tensiometric approach for evaluation of thermal mud quality
Authors: Rossi, Davide; Jobstraibizer, Pier Giorgio; Dal Bosco, Camilla; Bettero, Antonio
Journal: Journal of Adhesion Science and Technology
Year: 2012

Development of a tensiometric model for surface energy characterization of raw coffee beans
Authors: Rossi, Davide; Mioni, Enrico; Zancato, Mirella; Bettero, Antonio
Journal: Journal of Food Engineering
Year: 2012

1st National Catalogue of Innovations for Human Development in Albania
Authors: Uruci, Renata; Vuji, Marina; Rossi, Davide; Orefice, Simone; Turco, Lucia
Journal: Shtypshkronja Maluka (Publisher), Tirana, Albania
Year: 2012

Tenskinmetric evaluation of surface energy changes in adult skin: Evidence from 834 normal subjects monitored in controlled conditions
Authors: Dal Bosco, Camilla; Rossi, Davide; Brunetta, Andrea; Bettero, Antonio
Journal: Cosmetics
Year: 2014

The combined action TVS mud index/TVS skin test as an evaluation marker of skin functionality and thermal mud effectiveness
Authors: Rossi, Davide; Dal Bosco, Camilla; Bettero, Antonio
Journal: Journal of The Japanese Society of Balneology, Climatology and Physical Medicine
Year: 2015

Sun Chengwen | Thermochemistry | Best Researcher Award

Published on by Analytical Chemistry

Dr. Sun Chengwen | Thermochemistry | Best Researcher Award

Northeast Forestry University, China

👨‍🎓Profiles

📚 Early Academic Pursuits

Dr. Sun Chengwen embarked on his academic journey with a strong foundation in engineering. He completed his undergraduate studies at Harbin Engineering University from 2009 to 2013, focusing on power engineering and engineering thermophysics. Recognized for his outstanding academic performance, he was later awarded a government-sponsored opportunity to study abroad. His passion for energy research led him to pursue a Master-Doctor Combined Program at the Karlsruhe Institute of Technology, Germany (2021-2022), where he specialized in Thermal Energy Technology and Safety.

🏢 Professional Endeavors

Currently, Dr. Sun serves as an Associate Professor at the School of Mechanical and Electrical Engineering, Northeast Forestry University (since May 2023). His work primarily involves advanced combustion technologies, detonation wave propagation, and energy efficiency improvements in combustion chambers. His interdisciplinary experience, gained through both domestic and international collaborations, positions him as a key contributor to modern combustion research.

🔬 Contributions and Research Focus

Dr. Sun’s research is centered on Rotating Detonation Combustion Technology, an advanced approach to achieving higher propulsion efficiency and energy conversion rates. His doctoral project at Harbin Engineering University (2016-2023) focused on:
1️⃣ Explaining the formation of oblique shock waves and the behavior of detonation wave propagation in methane-air mixtures under single-point initiation.
2️⃣ Analyzing the supercharging performance of rotating detonation combustion chambers under various working conditions, contributing to improved energy output and efficiency.
3️⃣ Developing strategies to suppress pulsation and improve the uniformity of flow field distribution, enhancing combustion chamber stability and reducing emissions.

🌍 Impact and Influence

Dr. Sun’s research holds significant implications for aerospace propulsion, power generation, and sustainable combustion technology. His contributions aid in the development of low-emission, high-efficiency combustion systems, paving the way for next-generation propulsion technology. His work serves as a reference for industries seeking to optimize energy conversion and fuel utilization efficiency.

📖 Academic Citations and Recognition

Dr. Sun has been recognized for his scholarly contributions, with his doctoral research ranking in the Top 10% of his field. His findings on detonation wave behavior and combustion chamber optimization have been cited in various high-impact journals. His expertise is frequently sought after in combustion research circles, both in China and internationally.

🛠️ Technical Skills

Dr. Sun possesses expertise in:
✔ Rotating detonation wave analysis and simulation
✔ Computational Fluid Dynamics (CFD) for combustion modeling
✔ High-speed flow field visualization techniques
✔ Low-emission combustion chamber design
✔ Experimental validation of detonation combustion performance

🎓 Teaching Experience

As an Associate Professor, Dr. Sun actively mentors students in the fields of power engineering, thermophysics, and combustion technology. His teaching approach integrates theoretical knowledge with experimental applications, ensuring students gain hands-on experience in advanced energy systems.

🚀 Legacy and Future Contributions

Dr. Sun Chengwen is poised to make lasting contributions to clean energy and advanced propulsion systems. His research on low-emission detonation combustion technology aligns with global sustainability goals, making him a crucial figure in next-generation energy solutions. His future work will likely focus on expanding the application of rotating detonation technology in aerospace and power industries, further enhancing energy efficiency and environmental protection.

📖Notable Publications

  • Performance evaluation and outlet load improvement of a rotating detonation combustor with different outlet nozzles

    • Journal: International Journal of Hydrogen Energy
    • Year: 2021.04

  • Effects of diverging nozzle downstream on flow field parameters of rotating detonation combustor

    • Journal: Applied Science
    • Year: 2019.10

  • Effect of expansion outlet on continuous rotating detonation combustor

    • Conference: ICDER International Conference
    • Year: 2019.08

  • Effects of Airflow Velocity and Droplet Diameter on the Secondary Breakup Characteristics

    • Journal: AIAA Journal
    • Year: 2021.08

  • The formation and development of oblique detonation wave with different chemical reaction models

    • Journal: Aerospace Science and Technology
    • Year: 2021.07

  • A combined theory model for predicting the viscosity of water-based Newtonian nanofluids containing spherical oxide nanoparticles

    • Journal: Journal of Thermal Analysis and Calorimetry
    • Year: 2018.01