Hongyun Zhang | Icephobic Materials | Best Researcher Award

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Prof. Hongyun Zhang | Icephobic Materials | Best Researcher Award

Professor at Kaili University | China

Dr. Hongyun Zhang is a materials and surface-engineering researcher whose work focuses on the thermodynamic and microstructural design of superhydrophobic and ice-phobic surfaces, generating a coherent body of scholarship that has earned 270 citations, 19 publications, and a Scopus h-index of 9. His studies analyse the physics underlying wetting behaviour on engineered metallic substrates, using thermodynamic modelling to map relationships between surface morphology, adhesion work, and stability of wetting states. A central contribution of his research is the development of pillar-based microstructural models that explain how hierarchical roughness controls free-energy barriers, contact-angle hysteresis, and transitions between Cassie–Baxter and Wenzel states. This modelling framework not only clarifies the energetics of water-repellent surfaces but also guides rational design of self-cleaning and drag-reducing coatings. Dr. Zhang extends these principles into ice-phobicity by computing icing delay times and evaluating how micro-scale geometry reduces ice adhesion and enhances surface robustness under sub-zero conditions. His work employs a blend of theoretical analysis, computational modelling, and applied surface engineering, providing quantitative design tools for improving performance of metal-based components in aviation, transportation, energy infrastructure, and environmental protection systems. Across his publications, he maintains a strong emphasis on linking microstructure manipulation with measurable functional outcomes, contributing both conceptual clarity and practical direction to the advancement of surface physics and metallurgical materials engineering. His cumulative output demonstrates consistent impact, a focused research niche, and a meaningful contribution to the development of advanced hydrophobic and anti-icing technologies.

Profiles : Scopus | ORCID

Featured Publlications

Qin, Y., Zhang, H., Marlowe, N. M., & Chen, W. (2016). Evaluation of human papillomavirus detection by Abbott m2000 system on samples collected by FTA Elute Card in a Chinese HIV-1 positive population. Cited by 17

Zhang, H. (2025). Selection of second step micro-morphology for anti-icing surfaces based on icing time. Applied Surface Science. Cited by 4

Zhang, H., Yang, Y. L., Pan, J. F., & Zhang, X. K. (2018). Compare study between icephobicity and superhydrophobicity. Cited by 29

Zhang, H., Yang, Y. L., Pan, J. F., & Yang, J. (2018). Study for critical roughness based on interfacial energy. Cited by 8

Zhao, L., Wang, D., Zhang, H., & Zhi, H. (2016). Fine mapping of the RSC8 locus and expression analysis of candidate SMV resistance genes in soybean.  Cited by 28

Huijie Zhu | Functional Materials | Best Researcher Award

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Prof. Huijie Zhu | Functional Materials | Best Researcher Award

Professor at Luoyang Institute of Science and Technology | China

Professor Zhu Huijie is a leading environmental engineering researcher at Luoyang University of Technology, focusing on wastewater purification and sustainable sewage treatment systems. His research primarily revolves around the use of nanomaterials, particularly nanoscale zero-valent iron and photocatalytic heterojunctions, for efficient removal of heavy metals such as arsenic, molybdenum, and antimony from aqueous solutions. With 37 scientific publications, 954 citations, and an h-index of 10 on Scopus, Professor Zhu has established a strong international research presence. His significant works in Journal of Hazardous Materials, Nanomaterials, and Water explore adsorption mechanisms, catalyst design, and environmental remediation techniques. He has successfully translated laboratory findings into practical applications through more than ten large-scale sewage treatment projects, including high-capacity wastewater stations serving thousands of residents. Additionally, his authored books — “Solar Aeration-Reactive Wall-Stabilized Sediment Combined Treatment Technology for Black and Odorous Water Bodies” and “Schwertmannite Environmental Effects” — highlight his contribution to eco-friendly water management solutions. Professor Zhu’s work exemplifies the integration of fundamental research with real-world environmental engineering, advancing both the scientific understanding and technological implementation of green wastewater treatment systems.

Profile :  Scopus | ORCID

Featured Publications

Zhu, H., Fu, S., Zhang, H., Wu, X., Han, J., Ma, X., Rong, J., Chen, S., Chen, G., & Li, Y. (2025). Research on synchronous synthesis of schwertmannite for removal of Pb²⁺ from acidic wastewater. Crystals.

Wang, Y., Zhu, H., He, P., Li, M., Cao, Y., Du, Y., Wen, Y., Zhao, Y., Liu, X., & Song, Y. (2025). Two-dimensional silver bismuth oxide/bismuth molybdate Z-scheme heterojunctions with rich oxygen vacancies for improved pollutant degradation and bacterial inactivation. Crystals.

Fu, S., Chu, Z., Huang, Z., Dong, X., Bie, J., Yang, Z., Zhu, H., Pu, W., Wu, W., & Liu, B. (2024). Construction of Z-scheme AgCl/BiOCl heterojunction with oxygen vacancies for improved pollutant degradation and bacterial inactivation. RSC Advances.

Fu, S., Huang, Z., Wang, Y., Zheng, B., Yuan, W., Li, L., Deng, P., Zhu, H., Zhang, H., & Liu, B. (2024). Fabrication of a novel Z-scheme AgBiO₃/BiOCl heterojunction with excellent photocatalytic performance towards organic pollutant. Materials.

Shi, M., Zhang, Y., Hong, W., Liu, J., Zhu, H., Liu, X., Geng, Y., Cai, Z., Lin, S., & Ni, C. (2022). Mechanism of simultaneous lead and chromium removal from contaminated wastewater by a schwertmannite-like mineral. Environmental Science and Pollution Research.