Prof. Dr. Zenghui Qiu | Electrochemical energy | Best Researcher Award
Prof. Dr. Zenghui Qiu, +Beijing University of Chemical Technology, China
Dr. Zenghui Qiu is a distinguished researcher in material science and nanotechnology, specializing in electrochemistry, energy storage materials, supercapacitors, and electrocatalysis. He is affiliated with the College of Mathematics & Physics at Beijing University of Chemical Technology, China. His research contributions focus on hybrid electrochemical energy storage devices, with numerous publications in top-tier journals such as ACS Applied Materials & Interfaces, Nano Research, and Journal of Alloys and Compounds. As an active peer reviewer for leading scientific journals, Dr. Qiu plays a crucial role in advancing the field of electrochemical energy storage. His studies on MXene-based hydrogels, graphene composites, and zinc-ion capacitors have significantly impacted the development of next-generation energy storage technologies. Recognized for his expertise, he collaborates with top researchers and institutions worldwide, driving innovation in sustainable energy solutions. 🚀🔋
Google Scholar
Education 🎓📚
Dr. Zenghui Qiu pursued his academic journey in material science and electrochemistry, earning his advanced degrees from prestigious institutions. His research focused on the design and synthesis of high-performance energy storage materials, particularly for supercapacitors and hybrid electrochemical devices. Throughout his education, he specialized in MXene-based materials, graphene composites, and electrocatalytic nanomaterials, gaining expertise in their electrochemical properties and applications. He conducted extensive studies on polyaniline-intercalated Ti₃C₂Tₓ hydrogels, defect-reduced graphene oxide, and metal oxide heterostructures to enhance energy storage efficiency. His doctoral research led to the development of novel electrode architectures, optimizing their electrochemical performance for next-generation energy storage systems. With a strong foundation in physical chemistry and nanomaterials, Dr. Qiu has emerged as a leading scientist in the field, contributing significantly to advancements in sustainable energy. His educational background laid the foundation for his impactful research and global collaborations in energy storage and material science. ⚡🔍
Experience 🏢🔬
Dr. Zenghui Qiu has extensive research experience in electrochemical energy storage, material science, and nanotechnology. As a faculty member at the College of Mathematics & Physics, Beijing University of Chemical Technology, he has led multiple research projects focusing on high-performance supercapacitors, hybrid electrochemical devices, and electrocatalysts. He has authored numerous high-impact publications in leading journals, contributing to advancements in MXene-based hydrogels, defect-engineered graphene, and metal-oxide heterostructures. His expertise in energy storage materials has positioned him as a key reviewer for prestigious journals, including ACS Applied Materials & Interfaces, Nano Research, and Chemical Engineering Journal. Dr. Qiu collaborates with global research teams to develop sustainable energy solutions, working on next-generation energy storage systems with improved efficiency and durability. His research has influenced various applications, from portable electronics to large-scale energy storage, making significant strides in the field of electrochemical energy technologies. ⚙️🔋
Awards & Honors 🏅🥇
Dr. Zenghui Qiu has received multiple accolades for his contributions to material science and electrochemical energy storage. His groundbreaking work on high-performance supercapacitors and hybrid electrochemical devices has earned him recognition from top-tier scientific institutions. He has been honored with prestigious awards for his innovative research on MXene-based hydrogels and graphene composites, advancing the field of energy storage materials. His role as a distinguished reviewer for leading journals such as ACS Applied Materials & Interfaces and Nano Research has been acknowledged through editorial distinctions. Dr. Qiu’s contributions to electrocatalysis and energy storage have been recognized at international conferences, where he has received best paper and outstanding researcher awards. His work on high-energy-density zinc-ion capacitors has garnered significant attention, leading to multiple citations and collaborations with esteemed research groups. His commitment to advancing sustainable energy solutions continues to be celebrated worldwide. 🏆🔬
Research Focus 🔍⚡
Dr. Zenghui Qiu specializes in material science, nanotechnology, and electrochemical energy storage. His research focuses on designing and developing advanced supercapacitors, hybrid electrochemical devices, and electrocatalytic materials. He has made significant contributions to the study of MXene-based hydrogels, graphene composites, and metal oxide heterostructures for high-performance energy storage applications. His work explores the electrochemical properties of novel materials, enhancing their capacitance, cycling stability, and rate performance. He investigates the interfacial chemistry and charge transfer mechanisms of nanostructured electrodes, optimizing their functionality for real-world applications. Dr. Qiu’s research has led to breakthroughs in zinc-ion capacitors, asymmetric supercapacitors, and hydrogen evolution electrocatalysts, contributing to sustainable energy solutions. His work aims to bridge the gap between fundamental nanomaterials research and practical energy storage technologies, driving innovations in clean and renewable energy. 🌍🔋
Publication Top Notes
🔬 W. Yan, D. Wu, X. Zhang, Z. Zhang, H. Xu – “Contact enhancement effect: Extending the duration of contact state to enhance the output of contact-separation triboelectric nanogenerators” – Materials Today Communications, 2025 📄 (📑 0 citations)
⚡ S. Meng, P. Liao, X. Zhang, Z. Qiu, H. Xu – “Ti3C2TX@PPy-reduced graphene oxide heterostructure hydrogel for supercapacitor with excellent rate capability” – Journal of Alloys and Compounds, 2025 ⚙️ (📑 0 citations)