Chong-Qing Wan | Data Quality Enhancement | Best Researcher Award

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Prof. Chong-Qing Wan | Data Quality Enhancement | Best Researcher Award

Capital Normal University | China

Prof. Chong-Qing Wan is a distinguished professor in the Department of Chemistry at Capital Normal University, Beijing, recognized for his extensive contributions to functional coordination chemistry and framework materials, with a research record comprising 83 scientific documents, an h-index of 24, and 1,987 citations from 1,717 documents. He earned a BA in chemistry from Xinyang Normal University, an MS from Nankai University with research on coordination complexes, and later completed his PhD under Prof. Thomas C. W. Mak at The Chinese University of Hong Kong. His work spans the synthesis, characterization, and application of metal–organic frameworks (MOFs), covalent–organic frameworks (COFs), ionic-liquid-based hybrids, and energy-related materials. He has published impactful studies in Nature Communications, Angewandte Chemie, and Chemistry of Materials, contributing to advances in MOF/COF meltability, glass formation, proton-conductive crystalline ionic liquids, and atomically precise nanoclusters. His research interests include functional coordination complexes, energy-storage materials, photocatalysis, and phase-transition mechanisms in porous frameworks. Throughout his academic career, he has been recognized for high-impact publications and sustained contributions to materials chemistry. Continuing to advance the field through innovative synthesis strategies and collaborative research, he remains a leading figure in framework-based materials and functional molecular systems.

Profiles : Scopus | Orcid

Featured Publications

Xue, W. L., Li, G. Q., Chen, H., Han, Y. C., Feng, L., Gu, X. L., Hu, S. Y., Deng, Y. H., Tan, L., Dove, M. T., Li, W., Zhang, J., Dong, H., Chen, Z., Deng, W. H., Xu, G., & Wan, C.-Q. (2024). Melt-quenched glass formation of a family of metal–carboxylate frameworks. Nature Communications, 15, 2040.*

Gu, X. L., Zhao, L., Sun, J., Cui, X. K., Li, G. Q., Hu, S. Y., Deng, Y. H., Li, Z., Li, K., Wang, H., & Wan, C.-Q. (2024). Synthesis and properties of zwitterionic covalent organic framework (COF): The meltability strategy and processability. Chemistry of Materials, 36, 2674–2684.*

Xue, W.-L., Deng, W.-H., Chen, H., Liu, R.-H., Taylor, J. M., Li, Y.-K., Wang, L., Deng, Y.-H., Li, W.-H., Wen, Y.-Y., Wang, G.-E., Wan, C.-Q., & Xu, G. (2021). MOF-directed synthesis of crystalline ionic liquids with enhanced proton conduction. Angewandte Chemie International Edition, 60, 1290–1297.

Qin, Z., Sharma, S., Wan, C.-Q., Malola, S., Xu, W.-W., Häkkinen, H., & Li, G. (2021). A homoleptic alkynyl-ligated [Au₁₃Ag₁₆L₂₄]³⁻ cluster as a catalytically active eight-electron system. Angewandte Chemie International Edition, 60, 970–975.*

Qin, Z., Zhang, J., Wan, C.-Q., Liu, S., Abroshan, H., Jin, R., & Li, G. (2020). Atomically precise nanoclusters with reversible isomeric transformation for rotary nanomotors. Nature Communications, 11, 6019.*

Jiabao Li | Engineering | Research Excellence Award

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Mr. Jiabao Li | Engineering | Research Excellence Award

Yangzhou University | China

Mr. Jiabao Li is a materials scientist and electrochemical energy researcher specializing in sodium-ion batteries and capacitive deionization, with particular focus on electrode and electrolyte design for extreme temperature environments. He earned his bachelor’s and master’s degrees in applied chemistry from Anhui Agricultural University, followed by a Ph.D. in materials and optoelectronics from East China Normal University, including a joint research period at the Georgia Institute of Technology. Since completing his doctoral work, he has served as a lecturer and researcher, leading multiple competitive research projects in materials innovation and energy-storage systems. His work integrates experimental synthesis with computational tools such as DFT modeling and molecular dynamics simulations to advance high-performance sodium-ion storage materials. He has published 98 scientific documents, accumulating 5,410 citations across 4,235 referencing documents, with an h-index of 40, reflecting significant global impact in the fields of battery chemistry and electrochemical engineering. His awards include national and institutional scholarships that recognize excellence in scientific research and academic achievement. Overall, his career demonstrates sustained contributions to next-generation energy-storage technologies and the advancement of robust sodium-ion systems for low-temperature and high-efficiency applications.

Profile : Scopus

Featured Publications

Unveiling the neglected role of oxygen doping in nitrogen-doped carbon for enhanced capacitive deionization performance. Nature Communications, 2025.

Rapidly evaluating electrochemical performance of transition metal disulfides for lithium-ion batteries using machine learning classifier. Chemical Engineering Journal, 2025.

Ionic conductor-armored Li₃V₂(PO₄)₃: a robust electrode for lithium capture via capacitive desalination. Chemical Communications, 2025.

Anion screening in ether-based electrolytes for boosted sodium storage at low temperature. Energy Storage Materials, 2025.

Coordination-tuned Na₃V₂(PO₄)₃ cathodes for low-temperature sodium-ion batteries. Chemical Communications, 2025.