Assist Prof Dr. Xianshu Qiao | Electrocatalysis | Best Researcher Award

Assist Prof Dr. Xianshu Qiao | Electrocatalysis | Best Researcher Award

Jingdezhen Ceramic University, China

Author Profile

Orcid

🌱 Early Academic Pursuits

Dr. Xianshu Qiao’s journey in materials science began with a strong foundation in chemical engineering. She earned her Master’s degree in Chemical Engineering and Technology from Inner Mongolia University of Technology, China, where she developed a keen interest in chemical processes and reaction mechanisms. Her master’s dissertation, focused on the absorption of sulfur dioxide and the preparation of barium sulfate using a triethylene glycol and dimethyl sulfoxide system, showcased her ability to tackle complex chemical challenges. This early exposure to chemical processes not only honed her analytical skills but also laid the groundwork for her future exploration of catalysis and materials science.

Her academic pursuit reached new heights when she embarked on a Ph.D. program in Materials Science and Engineering at Harbin Institute of Technology, one of China’s top technical universities. Under the mentorship of distinguished professors Wei Qin and Xiaohong Wu, Dr. Qiao focused on the preparation of iridium and iron co-modified β-Ni(OH)₂ electrode materials, with a particular emphasis on their oxygen evolution performance. Her doctoral research was marked by a meticulous approach to material design and synthesis, leading to the development of highly efficient electrode materials. These experiences not only enriched her scientific knowledge but also cemented her passion for electrocatalysis, a field that would become the core of her research career.

💡 Professional Endeavors

Dr. Xianshu Qiao’s career as an academic and researcher has been defined by her role as an Associate Professor of Materials Science at Jingdezhen Ceramic University. In this position, she has seamlessly integrated teaching, mentorship, and research, shaping the next generation of scientists while advancing the field of materials science. Her dedication to education is evident in her ability to inspire students, instilling in them a strong foundation in scientific principles and a curiosity for research.

In her research, Dr. Qiao has established herself as a leading figure in the development of transition metal-based electrocatalysts. Her work centers on the rational design, controlled synthesis, and catalytic reaction mechanisms of materials, particularly those involving nickel, iron, and cobalt compounds. Her extensive research on these materials has led to significant advancements in the efficiency of oxygen evolution reaction (OER) and hydrogen evolution reaction (HER), two critical processes for sustainable energy conversion. As a researcher, she has demonstrated a rare ability to bridge theoretical insights with practical applications, making substantial contributions to the development of efficient, durable catalysts.

🔬 Contributions and Research Focus

Dr. Xianshu Qiao’s research is characterized by a deep understanding of transition metal-based electrocatalysts, particularly those involving nickel, iron, and cobalt. Her focus on the rational design and controlled synthesis of these materials has led to the development of catalysts with exceptional performance in OER and HER. These reactions are vital for renewable energy technologies, including water splitting and hydrogen production.

Her work has resulted in numerous high-impact publications, including 13 SCI papers as the first author in internationally recognized journals such as Applied Catalysis B: Environmental, Small, International Journal of Hydrogen Energy, ACS Applied Materials and Interfaces, and Inorganic Chemistry Frontiers. These publications reflect not only her expertise in the field but also her commitment to advancing scientific knowledge. In addition to her first-author publications, she has co-authored more than 30 SCI papers, demonstrating her ability to collaborate with other researchers and contribute to multidisciplinary projects.

One of her most notable achievements is the development of porous Fe-doped β-Ni(OH)₂ nanopyramid array electrodes for water splitting, a breakthrough that has been widely recognized in the field. Her innovative approach to catalyst design, involving electronic dual modulation and grain boundary engineering, has set a new standard for the performance of transition metal-based catalysts. This work has not only advanced the understanding of catalytic mechanisms but also paved the way for the development of next-generation energy storage and conversion technologies.

🏆 Accolades and Recognition

Dr. Xianshu Qiao’s contributions to materials science have earned her significant recognition in the scientific community. Her research has been published in some of the most prestigious journals in the field, and her work on transition metal-based electrocatalysts has been widely cited by peers worldwide. Her reputation as a leading researcher is further reinforced by her extensive publication record, which includes 13 first-author SCI papers and over 30 co-authored SCI papers.

Beyond her publications, Dr. Qiao has been recognized for her ability to mentor and inspire young researchers. Her role as an educator at Jingdezhen Ceramic University has allowed her to shape the careers of aspiring scientists, fostering a culture of academic excellence and intellectual curiosity. Her dedication to scientific rigor and innovation has made her a respected figure in the academic community.

🌍 Impact and Influence

The impact of Dr. Qiao’s research extends far beyond her publications. Her innovative work on efficient electrocatalysts has the potential to drive the development of sustainable energy solutions, contributing to global efforts to combat climate change. By improving the efficiency of OER and HER, her catalysts can enhance the performance of renewable energy systems, making them more viable for large-scale applications.

As an educator and mentor, Dr. Qiao has influenced the next generation of scientists, equipping them with the skills and knowledge needed to excel in their careers. Her ability to foster a collaborative and intellectually stimulating research environment has inspired many young researchers to pursue careers in materials science.

🌟 Legacy and Future Contributions

Dr. Xianshu Qiao’s legacy is one of scientific excellence, innovation, and mentorship. Her groundbreaking research on transition metal-based electrocatalysts has transformed the field of catalysis, providing new insights into the design and optimization of efficient, durable catalysts. As she continues to explore new materials and catalytic mechanisms, her work will likely lead to further advancements in sustainable energy technologies.

In the future, Dr. Qiao is expected to expand her research into new areas of energy conversion and storage, exploring the potential of novel materials and catalytic systems. Her commitment to education and mentorship will continue to shape the careers of young scientists, ensuring that her legacy endures for generations to come.

📝Notable Publications

 Hierarchical Ultrafine Nanosheet-Based O-Doped FeCoS₂ Microsphere Catalyst for Highly Efficient Oxygen Evolution Reaction

Author: Xianshu Qiao
Journal: International Journal of Hydrogen Energy
Year: 2025

Ultra-Small β-Ni(OH)₂ Quantum Dot Catalyst with Abundant Edges for an Efficient Urea Oxidation Reaction

Author: Xianshu Qiao
Journal: Inorganic Chemistry Frontiers
Year: 2025

Modulating Electronic Structure of Iridium Single-Atom Anchored on 3D Fe-Doped β-Ni(OH)₂ Catalyst with Nanopyramid Array Structure for Enhanced Oxygen Evolution Reaction

Author: Xianshu Qiao
Journal: Small
Year: 2024

 Grain Boundary Density and Electronic Dual Modulation of Intermetallic Co₂B by Fe Doping Toward Efficient Catalyst for Oxygen Evolution Reaction

Author: Xianshu Qiao
Journal: Applied Catalysis B: Environmental
Year: 2022

Novel FeNi-Based Nanowires Network Catalyst Involving Hydrophilic Channel for Oxygen Evolution Reaction

Author: Xianshu Qiao
Journal: Small
Year: 2022

Mr. Guangyao Li | adsorption | Best Researcher Award

Mr. Guangyao Li | adsorption | Best Researcher Award

kyushu university, Japan

Author Profile

Scopus

🌱 Early Academic Pursuits

Lee Kuan Yew’s journey in academia began with a strong foundation in engineering, a field that combines creativity, problem-solving, and technical knowledge. Hailing from Xinxiang, Henan, he pursued his undergraduate studies at Henan Polytechnic University, where he earned a Bachelor of Engineering in Mechanical Design. His education in this institution laid the groundwork for his understanding of core mechanical concepts, including Engineering Thermodynamics, Mechanical Design, and Automation Technology. These formative years instilled in him a profound appreciation for the principles of mechanics and thermodynamics, which would later become central to his research.

Driven by an unrelenting desire for advanced knowledge, Lee Kuan Yew furthered his studies at Zhengzhou University, a prestigious Double First-Class institution, where he earned a Master of Engineering in Power Engineering. His curriculum covered a wide range of subjects, from Advanced Heat Transfer and Fluid Mechanics to Numerical Analysis and Industrial Energy Management. These courses equipped him with both theoretical insights and practical skills, making him proficient in the nuances of energy systems. His academic prowess and enthusiasm for research led him to pursue a Ph.D. in Mechanical and System Engineering at Kyushu University in Japan, sponsored by the China Scholarship Council (CSC). At this renowned institution, he delved into complex topics like Thermal Energy Utilization Systems and Numerical Fluid Mechanics, honing his expertise in thermal engineering.

🚀 Professional Endeavors

Lee Kuan Yew’s professional journey has been marked by diverse and impactful experiences. Since 2022, he has been actively involved in the development of adsorption refrigeration and heat pump systems at Mitsubishi Electric Corporation. His role has been pivotal in designing and constructing a fixed-volume adsorption isotherm measurement device and analyzing the adsorption characteristics of materials for refrigerants like R245fa. This work not only refined his technical skills but also positioned him at the forefront of sustainable energy technology.

His expertise in adsorption technology further extended to collaborative research with ENEOS from 2022 to 2024, where he investigated the absorption characteristics of novel compressor oils and refrigerants under varying pressures and temperatures. His meticulous data collection and analysis contributed significantly to the development of advanced energy systems.

Lee Kuan Yew also played a critical role in a groundbreaking project with NEDO, focusing on carbon dioxide capture, storage, and utilization. Here, he developed a CO₂ absorption characteristic measurement device and formulated a mathematical model to analyze the absorption behavior of CO₂ using an amino + ether phase change solution. This work underscored his commitment to tackling global environmental challenges.

🔬 Contributions and Research Focus

Throughout his career, Lee Kuan Yew has made substantial contributions to the field of thermal energy and environmental technology. His research primarily revolves around adsorption heat pumps, absorption technology, and carbon capture. Notably, he has been involved in the development of high-performance adsorbents derived from biomass for carbon capture, merging experimental work with molecular simulations to optimize efficiency.

His research on adsorption heat pumps, including the development of a metal roller anti-stick coating for industrial applications, has showcased his ability to bridge theory with practice. Moreover, his work on fly ash-based zeolite synthesis, funded by the Henan Provincial Department of Science and Technology, demonstrated his dedication to sustainable material development.

Lee Kuan Yew has also authored several academic publications, including a paper on “Superhydrophobic Surface-modified Zeolite to Regulate the Migration of Nonadsorbed Liquid Water in an Open-loop Adsorption Heat Pump,” published in Applied Thermal Engineering. His other work on “Performance Improvement of Waste Heat Upgrading Adsorption Heat Pump by Employing Copper Oxide-Loaded Composite Zeolites for High-Temperature Steam Generation” is currently under review, further highlighting his ongoing commitment to advancing thermal engineering.

🏆 Accolades and Recognition

Lee Kuan Yew’s dedication to excellence has earned him numerous awards and recognitions. In 2021, he was honored as an Excellent Volunteer for Flood Control by the Henan Provincial Civilization Committee, a testament to his sense of responsibility and commitment to community welfare. During the COVID-19 pandemic, he received a Commendation for Fighting the Epidemic from the Communist Youth League of Xinxiang Municipal Committee, recognizing his willingness to serve during challenging times.

His academic excellence has also been acknowledged through scholarships awarded by the Henan Provincial Department of Education (2019-2022) and a Third Prize at the Zhengzhou University Graduate Innovation Competition in 2021. These honors not only reflect his intellectual abilities but also his perseverance and dedication.

🌐 Impact and Influence

Lee Kuan Yew’s work has had a profound impact on the field of thermal energy, particularly in the development of sustainable energy solutions. His research on adsorption heat pumps and carbon capture has the potential to revolutionize energy systems, making them more efficient and environmentally friendly. His active participation in industrial projects with Mitsubishi Electric Corporation and ENEOS has enabled him to bridge the gap between theoretical research and practical applications, creating technologies that can directly benefit society.

Moreover, his academic publications have enriched the scientific community’s understanding of adsorption and absorption processes, providing a foundation for future research in the field. His expertise in computational tools such as Material Studio, CAD, SolidWorks, and Comsol further enhances his ability to drive innovation.

🌟 Legacy and Future Contributions

As a young scholar and engineer with a passion for sustainability, Lee Kuan Yew’s journey is far from over. His continuous pursuit of excellence in research and his ability to translate complex scientific concepts into real-world solutions position him as a promising leader in the field of thermal energy. Moving forward, he aims to explore new frontiers in energy conversion and environmental technology, contributing to a greener, more sustainable world.

📝Notable Publications

Performance Improvement of Waste Heat Upgrading Adsorption Heat Pump by Employing Copper Oxide-Loaded Composite Zeolites for High-Temperature Steam Generation

Authors: G. Li (Guangyao), B. Xue (Bing), H. Yu (Hao), K. Thu (Kyaw), T. Miyazaki (Takahiko)
Journal: Colloids and Surfaces A: Physicochemical and Engineering Aspects
Year: 2025