Wenyuan Fang | Chemical Engineering | Best Researcher Award

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Assist Prof Dr. Wenyuan Fang | Chemical Engineering | Best Researcher Award 

Jining Medical University | China

Dr. Wenyuan Fang is a dedicated researcher and academic in the field of pharmaceutical sciences, with a strong specialization in glycoengineering, functional oligosaccharides, and glycopeptide drug development. Fang research contributions demonstrate a significant commitment to advancing innovative strategies for the synthesis, design, and pharmacological evaluation of bioactive oligosaccharides and glycopeptide-based therapeutics. Over the years, Fang has built a solid body of work that integrates organic synthesis, enzymatic methodologies, glycosylation mechanisms, and functional material applications. This multidisciplinary approach has enabled to contribute meaningfully to drug discovery, targeted drug delivery, and the development of functional biomaterials. Her research focuses on several key areas, including the development of novel drug candidates derived from bioactive oligosaccharides, advanced chemoenzymatic synthesis strategies, the study of glycopeptide function, pharmacodynamic analysis of peptide drugs, glycan functional materials, and delivery systems for therapeutic peptides. Fang scholarly output includes publications in highly regarded journals such as Biotechnology Advances, Biomolecules, Chemistry – A European Journal, Chinese Journal of Chemistry, Journal of Materials Chemistry A, and Journal of Materials Science. These works reflect both depth and innovation, with several papers recognized as cover features or frontispieces, highlighting their scientific importance and impact. Fang contributions to oligosaccharide synthesis—particularly rapid enzymatic assembly, functional membrane development, and advanced material fabrication—demonstrate ability to bridge traditional pharmaceutical sciences with material chemistry and biomolecular engineering. Fang’s recent publications also showcase progress in the chemoenzymatic construction of human blood group antigens and the development of synthetic strategies for bioactive oligosaccharides, reinforcing the expertise in glycoscience and its translational potential. Fang has participated in funded research projects, including those supported by regional science foundations, contributing to the advancement of drug development technologies and the understanding of glycan structure–function relationships. Beyond research, Fang’s academic involvement includes collaboration with multidisciplinary teams, fostering an environment of scientific exchange and innovation. Wenyuan Fang work supports the development of next-generation therapeutic strategies and holds strong potential for real-world applications in pharmaceutical formulation, biomaterials, and biomedical research. Through consistent scholarly engagement, innovative project involvement, and contributions to scientific literature, Wenyuan Fang exemplifies a strong commitment to advancing pharmaceutical and glycoengineering research. Fang achievements reflect not only scientific rigor but also the potential to influence future developments in drug design, therapeutic delivery, and functional biomaterial innovation.

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Featured Publications

Cai Xiaolong | Chemical Engineering | Research Excellence Award

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Mr. Cai Xiaolong | Chemical Engineering | Research Excellence Award 

YuLin University | China

Mr. Cai Xiaolong (also cited as Cai Xiaolin) is an emerging researcher in materials science and photocatalysis, with a primary affiliation at the College of New Energy and the College of Chemistry and Chemical Engineering, Yulin University, Yulin 719000, China. His work focuses on the design, synthesis, and optimization of advanced semiconductor photocatalysts for sustainable energy conversion and environmental applications — especially solar-driven CO₂ reduction and related redox reactions using visible light. A central theme in Mr. Cai’s research is the controllable synthesis and structural modulation of bismuth-based photocatalytic materials, with particular emphasis on bismuth oxybromide (Bi₄O₅Br₂) and other Bi-oxyhalide phases. These layered semiconductor compounds are of interest because their tunable band structures and internal electric fields can enhance the generation and separation of photogenerated charge carriers under visible light irradiation — properties that are key to efficient photocatalysis. MDPI In his recently published work, Mr. Cai led efforts to develop hydrothermal synthesis strategies that manipulate precursor chemistry — such as the Bi:Br molar ratio and solution pH — to achieve controlled formation of Bi₄O₅Br₂, BiOBr, and Bi₅O₇Br phases with varied morphologies and photocatalytic performance. This research demonstrates how careful tuning of synthesis parameters can yield materials with improved light absorption, tailored morphologies (e.g., microspheres, polyhedrons), and enhanced performance in the photocatalytic reduction of CO₂ to CO. Among the synthesized catalysts, certain Bi₄O₅Br₂ structures achieved record rates of CO production and competitive selectivity under visible-light conditions, illustrating the potential of phase-engineered bismuth oxybromides for solar fuel generation. MDPI Mr. Cai’s contributions extend to understanding how intrinsic material properties such as band gap, charge separation efficiency, and surface adsorption behavior impact photocatalytic pathways. His approach integrates materials chemistry, advanced structural characterization, and catalytic testing, aiming to bridge fundamental insights with application-oriented outcomes. As part of a wider research community exploring Bi-rich oxyhalides, related strategies include heterojunction construction, dopant engineering, and oxygen-vacancy modulation — all intended to further enhance visible-light activity and product specificity. RSC Publishing Overall, Mr. Cai Xiaolong’s work contributes to the development of next-generation photocatalytic materials that address global challenges in carbon utilization and renewable energy, positioning him as a notable scholar in photocatalytic CO₂ conversion and sustainable materials design.

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Featured Publications

Qingguo Ma | Chemical Engineering | Excellence in Innovation Award

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Dr. Qingguo Ma | Chemical Engineering | Excellence in Innovation Award

Taiyuan Institute of Technology | China

Dr. Qingguo Ma, an accomplished Associate Professor at the Taiyuan Institute of Technology, is a distinguished researcher specializing in advanced wastewater treatment, particularly in the catalytic degradation of formaldehyde. With a doctoral degree obtained from the School of Chemical Engineering and Technology at Nanjing University of Science and Technology, Dr. Ma has established a focused research trajectory in the development of innovative and efficient oxidation-based solutions for industrial pollutant removal. His work emphasizes the use of advanced oxidation processes employing oxidants such as hydrogen peroxide and monopersulfate in conjunction with highly efficient catalytic systems, including transition metal oxides and lanthanum-based composite metal oxide catalysts. Through this research, Dr. Ma has successfully achieved remarkable improvements in formaldehyde degradation efficiency, notably demonstrating degradation rates exceeding 90% under ambient conditions without the need for acidic, alkaline, photochemical, or electrocatalytic environments. This breakthrough shortens the oxidative degradation time by up to 12 times compared to conventional heterogeneous catalysts and provides a scalable pathway toward cost-effective and energy-efficient wastewater treatment technologies. Dr. Ma’s academic contributions are supported by a robust research profile, including five completed or ongoing research projects, eleven patents published or under application, and thirteen peer-reviewed publications indexed in SCI databases. His work has attracted growing scholarly attention, reflected in a developing citation index and engagement in two consultancy or industry-linked research initiatives. As a member of the Shanxi Provincial Society for Inspection and Testing, he actively contributes to the advancement of environmental monitoring and chemical engineering practices within the professional community. His research further explores the mechanistic pathways of formaldehyde oxidation, identifying both radical-driven and non-radical catalytic routes, which enhances scientific understanding and offers new design concepts for catalytic materials used in environmental remediation. Dr. Ma continues to expand collaborations and strengthen knowledge transfer through academic platforms, contributing meaningfully to scientific and societal progress in pollution control. With demonstrated excellence, innovation, and commitment to advancing sustainable wastewater treatment technologies, he exemplifies the qualities recognized by the Excellence in Innovation Award. Dr. Ma affirms the authenticity and accuracy of all information included in this application and acknowledges the guidelines and terms set forth for this nomination.

Profiles: Scopus | Orcid

Featured Publications

Ma, Q. (2024). Preparation of perovskite-type LaMnO₃ and its catalytic degradation of formaldehyde in wastewater. Molecules, 29(16). https://doi.org/10.3390/molecules29163822

Ma, Q. (2023). Removal of formaldehyde in water with low concentration of hydrogen peroxide catalyzed by lanthanum–silicon oxide composite. Desalination and Water Treatment, 29734. https://doi.org/10.5004/dwt.2023.29734

Ma, Q. (2023). The Baeyer–Villiger oxidation of cycloketones using hydrogen peroxide as an oxidant. Catalysts, 13(1). https://doi.org/10.3390/catal13010021

Ma, Q. (2022). Removal of formaldehyde from aqueous solution by hydrogen peroxide. Journal of Water Chemistry and Technology, 44(4). https://doi.org/10.3103/S1063455X22040099

Ma, Q. (2021). Enhancing propene selectivity in methanol and/or butene conversion by regulating channel systems over ZSM-5/ZSM-48 composite zeolites. Microporous and Mesoporous Materials, 310. https://doi.org/10.1016/j.micromeso.2020.110803

Ma, Q. (2015). Baeyer–Villiger oxidation of cyclic ketones with hydrogen peroxide catalyzed by silica–VTMO–OSO₃H. Journal of Porous Materials, 22(5). https://doi.org/10.1007/s10934-015-9918-8

Ma, Q. (2015). Silica/A153-SO₃H: An efficient catalyst for the Baeyer–Villiger oxidation of cyclic ketones with hydrogen peroxide. Comptes Rendus Chimie, 18(4). https://doi.org/10.1016/j.crci.2014.09.002

Ma, Q. (2015). Sn-bentonite-induced Baeyer–Villiger oxidation of 2-heptylcyclopentanone to δ-dodecalactone with aqueous hydrogen peroxide. Research on Chemical Intermediates, 41(5). https://doi.org/10.1007/s11164-013-1342-6