Xikui Wang | Nano Manufacturing | Best Researcher Award

Dr. Xikui Wang 👨‍🔬, born in October 1987, is an Associate Professor at the School of Mechanical Engineering, Guizhou University, China 🇨🇳. His expertise lies in Materials Science and Engineering, focusing on bionic super-wetting coatings and intelligent surface designs 🌊🧪. A senior member of multiple prestigious societies including the Chinese Mechanical Engineering Society and the International Society of Bionic Engineering 🤝, Dr. Wang is also an active reviewer for high-impact journals like ACS Applied Materials & Interfaces and Applied Surface Science 📚. He earned his Ph.D. in 2019 and continues to lead innovative research in materials and nanotechnology 🔬.

Publication Profiles

Orcid

Scopus 

 Education & Experience 

• 🎓 Ph.D. in Materials Science and Engineering, Southeast University (2016.03–2019.09)

• 🎓 Master’s in Mechanical Manufacturing and Automation, Guizhou University (2012.09–2015.07)

• 🎓 Bachelor’s in Material Forming and Control Engineering, Guizhou University (2008.09–2012.07)

• 👨‍🏫 Associate Professor, School of Mechanical Engineering, Guizhou University

Summary Suitability For The Award

Assoc. Prof. Dr. Xikui Wang, a distinguished scholar at Guizhou University, China, stands out as a top contender for the Best Researcher Award owing to his impactful and interdisciplinary contributions to Materials Science and Engineering. With a Ph.D. from Southeast University, Dr. Wang has pioneered innovative research in bionic super-wetting surfaces, micro/nano-manufacturing, and corrosion-resistant coatings. His work is inspired by biological phenomena—like desert beetles and pitcher plants—and applies these insights to address real-world challenges such as water scarcity, climate resilience, and industrial corrosion.

 Professional Development

Dr. Wang has actively expanded his academic and scientific influence through participation in interdisciplinary research and professional societies 🧠🌐. He is a senior member of the Chinese Mechanical Engineering Society, a member of the International Society of Bionic Engineering, and the Chinese Composites Society 🏛️. His editorial and peer-review contributions to renowned journals like Journal of Materials Chemistry A, Energy, and ACS Applied Materials & Interfaces reflect his respected standing in the academic community 📖📝. Dr. Wang frequently collaborates across disciplines, pushing the frontiers of micro/nano manufacturing and bionic surface design for real-world applications 🌍🔧.

 Research Focus 

Dr. Wang’s research revolves around bionic intelligent structures, micro/nano manufacturing, and functional coatings 🧬🛠️. He designs superhydrophobic and superdihydrophobic surfaces inspired by nature, applying them in water harvesting, anti-icing, self-cleaning, and anti-condensation technologies ❄️💧. Utilizing ultrasound, laser, and additive manufacturing techniques, his work draws inspiration from organisms like desert beetles and spider silk 🕷️🐞. Additionally, he focuses on corrosion-resistant coatings for extreme environments 🛡️🌫️. His research bridges nature and engineering, delivering eco-friendly and sustainable solutions for climate resilience, energy efficiency, and industrial performance 🌱⚙️.

 Awards & Honors 

• 🧑‍🔬 Recognized Reviewer for top journals: ACS Applied Materials & Interfaces, Journal of Materials Chemistry A, Energy, Applied Surface Science

• 🧑‍💼 Senior Member, Chinese Mechanical Engineering Society

• 🌍 Member, International Society of Bionic Engineering

• 🧵 Member, Chinese Composites Society

Publication Top Noted

1. Efficient fog harvesting system inspired by cactus spine and spider silk with vertical crisscross spindle structure (2025) 

2. Bioinspired 1D structures for water harvesting: Theory, design and application (2025) 

3. Smart Materials and Micro/Nanoarchitectonics for Water Harvesting: From Fundamental Mechanism to Advanced Application (2024) 

4. Superamphiphobic coatings with polymer-wrapped particles: enhancing water harvesting (2019) – Cited by: 154  

5. Water harvesting method via a hybrid superwettable coating with superhydrophobic and superhydrophilic nanoparticles (2019) – Cited by: 198  

6. Enhancing Nucleation and Detachment of Condensed Drops by Hybrid Wetting Surfaces (2018) – Cited by: 74