Professor | Dalian University of Technology | China
Prof. Qingwei Meng is a distinguished scholar in Pharmaceutical Engineering whose academic journey and research excellence have significantly shaped modern pharmaceutical science. His expertise in Pharmaceutical Engineering encompasses intelligent continuous pharmaceutical manufacturing, visible-light photocatalysis, asymmetric catalysis, and the development of innovative anti-aging and anti-cancer drugs. With a strong foundation in Pharmaceutical Engineering, Prof. Meng has contributed to the development and approval of one Class 1 new drug and two Class 2 new drugs, reflecting his practical and scientific leadership. His professional experience in Pharmaceutical Engineering has led to numerous accolades, including the First Prize of the Dalian Patent Award and the Dalian Technology Invention Award. A Liaoning Distinguished Professor and Ph.D. Supervisor, he integrates Pharmaceutical Engineering principles with eco-friendly approaches, exemplified in his research on vitamin quantification using green HPLC-UV techniques. His research interests in Pharmaceutical Engineering extend to sustainable and intelligent drug production systems that improve efficiency and therapeutic outcomes. Prof. Meng’s outstanding contributions have made him a leader in Pharmaceutical Engineering innovation, bridging industrial applications with academic research. His skills in Pharmaceutical Engineering analysis, catalysis, and molecular synthesis have advanced the field toward a more intelligent and environmentally responsible future. Through dedication and collaboration, he continues to elevate the global standard of Pharmaceutical Engineering, inspiring future scientists and fostering technological advancement. Scopus profile of 1,406 Citations, 121 Documents, 24 h-index.
Profiles: Scopus | ORCID
Featured Publications
1. Simultaneous quantification of 12 water-soluble vitamins in MDCK cell culture media by eco-friendly ion-pairing reagent-free HPLC-UV. (2025). Scientific Reports.
2. Harnessing methanol as a C1 source for tunable C–H functionalization over CdS-based photocatalysts. (2025). Journal of Catalysis.
3. Anionic sulfur quantum dots as reductive photocatalysts via the Auger process for dehalogenation reactions. (2025). Industrial and Engineering Chemistry Research.
4. Accelerating transition state search and ligand screening for organometallic catalysis with reactive machine learning potential. (2025). Journal of Chemical Theory and Computation.
5. Iron-anthraquinone cooperative catalysis enables mild C–C bond cleavage of cyclohexanones via oxygen-centered radicals. (2025). Chemical Communications.