Yuan Ping | Chemistry and Materials Science | Research Excellence Award

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Assoc. Prof. Dr. Yuan Ping | Chemistry and Materials Science | Research Excellence Award

University of Wisconsin | United States

Assoc. Prof. Dr. Yuan Ping is a leading theoretical materials scientist whose research focuses on first-principles many-body theory and open quantum dynamics to understand excited-state and spin-dependent phenomena in solids. Her work advances the predictive modeling of optoelectronic properties, quasiparticle dynamics (excitons, polarons, magnons), and quantum defects in low-dimensional and hybrid materials. She has made foundational contributions to density-matrix–based quantum dynamics, spin-optronics, chiral and nonlinear optical responses, and defect-based quantum technologies, bridging fundamental theory with applications in quantum information science, low-power electronics, and energy conversion.

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Featured Publications


Simultaneous enhancements in photon absorption and charge transport of bismuth vanadate photoanodes for solar water splitting

– TW Kim, Y Ping, GA Galli, KS Choi – Nature Communications, 2015 · Cited by 606


Ruthenium atomically dispersed in carbon outperforms platinum toward hydrogen evolution in alkaline media

– B Lu, L Guo, F Wu, Y Peng, JE Lu, et al. – Nature Communications, 2019 · Cited by 599


The Reaction Mechanism with Free Energy Barriers at Constant Potentials for the Oxygen Evolution Reaction at the IrO2 (110) Surface

– Y Ping, RJ Nielsen, WA Goddard III – Journal of the American Chemical Society, 2017 · Cited by 362


Modelling heterogeneous interfaces for solar water splitting

– TA Pham, Y Ping, G Galli – Nature Materials, 2017 · Cited by 334


Theoretical and Experimental Insight into the Effect of Nitrogen Doping on Hydrogen Evolution Activity of Ni3S2 in Alkaline Medium

– T Kou, T Smart, B Yao, I Chen, D Thota, Y Ping, Y Li – Advanced Energy Materials, 2018 · Cited by 287

Shuai Zhao | 2D Materials and Beyond | Best Researcher Award

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Dr. Shuai Zhao | 2D Materials and Beyond | Best Researcher Award

Soochow University | China

Dr. Shuai Zhao, is a distinguished researcher specializing in organic functional molecular low-dimensional materials and optoelectronics, focusing on the design, programmable self-assembly, and cascade energy conversion mechanisms of organic cocrystals and heterostructures. His research has achieved significant breakthroughs in molecular systems, controllable synthesis, and mechanism elucidation, enabling precise fabrication of multicomponent block heterostructures and advanced optical materials. Dr. Shuai Zhao authored 8 peer-reviewed publications, in high-impact journals such as J. Am. Chem. Soc., Angew. Chem. Int. Ed., Adv. Funct. Mater., Nano Lett., and Small, contributing to scalable synthesis of organic core/shell architectures, dual- and multi-wavelength optical waveguides, and continuously tunable organic cocrystal alloys for photonic integration and display applications. His work is cited 26 times across 21 documents, with an h-index of 2, reflecting his growing impact in the field. He holds a granted Chinese invention patent and has secured competitive research funding, including the National Natural Science Foundation of China (Youth Program) and the Natural Science Foundation of Jiangsu Province (Youth Program). Dr. Shuai Zhao’s pioneering work on stepwise epitaxial growth, programmable in-situ co-assembly, and dynamic control of optical outputs has advanced understanding of structure–property relationships in low-dimensional organic materials. Recognized through postdoctoral talent awards and provincial excellence programs, he actively contributes to the research community via editorial service, peer review, and development of novel strategies for molecular design, photonic device integration, and multifunctional organic optical materials, establishing him as a leading figure in organic optoelectronic research.

Profile: Scopus

Featured Publications

  • Zhao, S., Zhang, J.-X., Wang, L., Xu, C.-F., Ma, Y., Wang, X.-D., & Liao, L.-S. (2025). Stepwise epitaxial growth of core-shell organic crystals for advanced dual-emission optical applications. Journal of the American Chemical Society, 47, 15510–15518. https://doi.org/10.1021/jacs.2025xxxx

  • Zhao, S., Zhang, J.-X., Xu, C.-F., Ma, Y., Luo, J.-H., Lin, H., Shi, Y., Wang, X.-D., & Liao, L.-S. (2024). Programmable in-situ co-assembly of organic multi-block nanowires for cascade optical waveguides. Angewandte Chemie International Edition, 63, e202412712. https://doi.org/10.1002/anie.202412712

  • Jiang, J.-H., Zhao, S., Sun, Y., & Wang, X.-D.* (2025). From binary to higher-order organic cocrystals: Design principles and performance optimization. Angewandte Chemie International Edition, 64, e202507102. https://doi.org/10.1002/anie.202507102

  • Deng, X.-Y., Zhao, S., Zhang, J.-X., Tu, J.-N., Lv, Z.-J., Zhang, X., Lu, J.-Y., Hu, Y., Zhao, C., Shi, Y.-L., & Wang, X.-D. (2025). Molecular-template vertical epitaxial growth of two-dimensional stacked organic cocrystal. Advanced Materials, in minor review.

  • Zhang, J.-X., Zhao, S., Lu, Z., & Wang, X.-D.* (2025). Flourishing organic active optical waveguides with diversity and creativity. Advanced Functional Materials, e06412. https://doi.org/10.1002/adfm.202506412