Mr. Jin Zhang | Catalysis | lecturer at Kunming University of Science and Technology, China
Dr. Jin Zhang is a Lecturer at Kunming University of Science and Technology, specializing in environmental catalysis and energy conversion. He earned his Ph.D. in Engineering from South China University of Technology, focusing on Environmental Science and Engineering. With over 12 SCI/Scopus-indexed publications, his research has been widely recognized, accumulating more than 570 citations with an H-index of 8. His work primarily revolves around air pollution control, CO and VOCs catalytic conversion, methane and CO₂ utilization, and energy catalysis. Dr. Zhang has successfully completed three major research projects and holds three patents, showcasing his commitment to innovation. His groundbreaking contributions include the development of high-performance non-precious metal catalysts that surpass traditional precious metal catalysts in efficiency. He has also introduced novel Mo@VN/V₂O₃-Co₃O₄ composite materials for potassium-oxygen batteries, demonstrating excellent catalytic performance. His extensive research and technological advancements make him a prominent figure in his field.
Professional Profile :
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Summary of Suitability for Award:
Dr. Jin Zhang is highly deserving of the “Excellence in Research” award due to his outstanding contributions to environmental science, catalysis, and energy research. His work on air pollution control and catalytic conversion has led to groundbreaking advancements in the development of high-performance, non-precious metal catalysts that outperform traditional precious metal-based systems. With over 12 SCI-indexed publications, 570 citations, and an H-index of 8, his research has had a significant impact on the scientific community. His pioneering work in energy catalysis has led to innovative materials such as the Mo@VN/V₂O₃-Co₃O₄ composite, which has demonstrated exceptional performance in potassium-oxygen batteries. Additionally, Dr. Zhang has secured multiple research grants, published patents, and contributed to industry collaborations, further reinforcing his excellence in applied research.Dr. Jin Zhang’s exceptional research achievements, high-impact publications, and groundbreaking innovations make him a perfect candidate for the “Excellence in Research award”. His contributions to sustainable energy and environmental protection have advanced the field significantly, demonstrating both academic rigor and real-world applicability. His work aligns perfectly with the award’s criteria, recognizing researchers who push the boundaries of knowledge and innovation in their respective field.
🎓Education:
Dr. Jin Zhang pursued his Ph.D. in Engineering from South China University of Technology, specializing in Environmental Science and Engineering. During his doctoral studies, he focused on advanced catalysis for air pollution control and energy applications, contributing to sustainable environmental solutions. His research explored VOC oxidation, methane activation, and CO₂ conversion using highly efficient, low-cost catalysts. He developed novel catalytic materials and mechanisms that significantly improved environmental remediation and clean energy production. His educational background equipped him with strong expertise in catalytic reaction mechanisms, material characterization, and sustainable energy applications. He gained hands-on experience with nanostructured catalysts, reaction engineering, and electrochemical systems, allowing him to bridge the gap between fundamental research and practical industrial applications. His work has been instrumental in developing high-performance catalysts for energy storage devices, air purification systems, and emission reduction technologies, contributing to both academia and industry.
🏢Work Experience:
Dr. Jin Zhang has extensive research experience in catalysis, environmental chemistry, and energy conversion. As a Lecturer at Kunming University of Science and Technology, he has been actively engaged in teaching, mentoring students, and conducting cutting-edge research. His expertise in non-precious metal catalysts has led to significant advancements in air pollution control and energy storage technologies. He has successfully completed three major research projects focused on CO and VOCs catalytic oxidation, methane conversion, and CO₂ utilization. Additionally, he has collaborated on two industry-sponsored consultancy projects, addressing real-world environmental and energy challenges. His work has resulted in three patents, demonstrating his innovative approach to developing high-performance catalytic materials. Dr. Zhang has also contributed to editorial and peer-reviewing activities for reputed journals. His collaborations with national and international researchers have enhanced his global research impact, making him a key player in green catalysis and sustainable energy.
🏅Awards:
Dr. Jin Zhang has received several prestigious accolades for his contributions to environmental science and catalysis research. He was honored with the Young Scientist Award for his outstanding work in air pollution control and catalytic conversion technologies. His innovative research on non-precious metal catalysts has been widely recognized, earning him Best Paper Awards in reputed journals. Additionally, he received the Outstanding Researcher Award for his advancements in energy catalysis and sustainable environmental technologies. Dr. Zhang has also been acknowledged by Kunming University of Science and Technology for his exemplary academic contributions. His work in designing high-performance catalysts has garnered industry recognition, leading to invitations as a keynote speaker at international conferences. His patents on novel catalytic materials have further cemented his reputation as a pioneering scientist in the field. His research excellence is also reflected in the high citation count of his publications, emphasizing the impact of his work.
🔬Research Focus:
Dr. Jin Zhang specializes in air pollution control and catalytic conversion technologies, focusing on the development of advanced non-precious metal catalysts for efficient oxidation reactions. His research targets the conversion of CO, VOCs, CH₄, and CO₂ into environmentally benign compounds, contributing to cleaner air and sustainable energy solutions. He has successfully developed high-performance catalysts whose oxidation efficiency surpasses that of conventional precious metal catalysts, making them cost-effective alternatives. His work in energy catalysis extends to designing novel materials for air batteries and fuel cells, enhancing their efficiency and stability. A major breakthrough in his research is the development of a Mo@VN/V₂O₃-Co₃O₄ composite material, which has demonstrated exceptional performance in potassium-oxygen batteries. His innovations hold promise for renewable energy applications and industrial-scale pollutant reduction. Dr. Zhang’s interdisciplinary approach integrates materials science, environmental chemistry, and catalysis engineering, driving impactful advancements in sustainable energy technologies.
Publication Top Notes:
Recent advances in recycle of industrial solid waste for the removal of SO₂ and NOₓ based on solid waste sorts, removal technologies and mechanism
Research progress on red mud for carbon-containing air pollution control
Insight into catalytic performance and reaction mechanism for toluene total oxidation over Cu-Ce supported catalyst
Tracking of Active Sites as Well as the Compositing Effect over a Cu/Ce-Based Catalyst with Superior Catalytic Activity
Hydrolysis of carbonyl sulfide using non-ionic surfactant-modified mesoporous γ-Al₂O₃ catalysts with high efficiency
Ultrasonic-enhanced phosphorus sludge excited O₃ coupled red mud simultaneous desulfurization and denitrification
Scalable Fabrication of Superhydrophobic Coating with Rough Coral Reef‐Like Structures for Efficient Self‐Cleaning and Oil‐Water Separation: An Experimental and Molecular Dynamics Simulation Study
Unravelling the role of oxygen species in toluene oxidation over Co₃O₄-base catalysts: In situ DRIFTS coupled with quasi in situ XPS
Static and dynamic quantification tracking of asymmetric oxygen vacancies in copper-ceria catalysts with superior catalytic activity
Effective regeneration of anode material recycled from scrapped Li-ion batteries
Direct regeneration of recycled cathode material mixture from scrapped LiFePO₄ batteries