Guoqin Cao | Surface Chemistry | Research Excellence Award

Published on by Analytical Chemistry

Assoc. Prof. Dr. Guoqin Cao | Surface Chemistry | Research Excellence Award

Zhengzhou University | China

Dr. Guoqin Cao is an Associate Professor of Materials Science and Engineering at Zhengzhou University and a member of the National Key Laboratory. His research focuses on advanced surface coatings and metallurgical mechanisms for metallic materials operating in extreme environments, particularly nuclear and high-temperature marine conditions. He has developed Zr–Si multi-interface kinetic modulation strategies and proposed the “siliconization–oxidation” phase selection theory, enabling atomic-scale control of oxidation and phase evolution. His work has significantly advanced oxidation-resistant, high-entropy, and amorphous coating systems. Dr. Cao has published over 40 papers, holds multiple patents, secured national funding, and actively mentors students and serves on international journal editorial boards.

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Yongli Song | Electrochemistry | Best Researcher Award

Published on by Analytical Chemistry

Dr. Yongli Song | Electrochemistry | Best Researcher Award

Jiangsu University | China

Profiles

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Early Academic Pursuits

Dr. Yongli Song embarked on his academic journey in the field of physics, where he cultivated a strong foundation in optics and condensed matter physics. His early education at a prestigious institute allowed him to develop a solid understanding of material properties and physical principles, which later served as the bedrock for his transition into energy materials research. His doctoral studies were particularly significant, where under the guidance of accomplished mentors, he focused on advanced functional materials and solid-state phenomena. This phase honed his analytical thinking and laid the groundwork for his future research endeavors in electrochemistry and energy storage technologies.

Professional Endeavors

Following his academic training, Dr. Song pursued postdoctoral research at a leading national university, where he deepened his specialization in solid-state electrolytes and lithium battery systems. He continued to work in this field as an assistant researcher, contributing to nationally recognized projects aimed at next-generation energy solutions. Eventually, he joined Jiangsu University as an assistant professor in the School of Energy and Power Engineering, where he leads independent research initiatives in lithium-ion and solid-state battery technologies. His professional path illustrates a steady progression marked by increased responsibility, scientific leadership, and impactful research contributions.

Contributions and Research Focus

Dr. Song’s research primarily centers on solid electrolytes for lithium-ion and solid-state batteries, addressing key challenges such as ionic conductivity, electrode compatibility, and dendrite suppression. His work spans metal chloride, oxide, and polymer-based solid electrolytes, aiming to optimize material properties for commercial viability and safety in energy storage systems. He has systematically explored the electrochemical stability of various materials, the development of novel transport channels, and mechanisms behind interface degradation and dendrite formation. His interdisciplinary approach integrates concepts from physics, materials science, and electrochemistry to design robust and efficient battery systems for real-world applications.

Impact and Influence

Dr. Song has published extensively in high-impact journals such as Advanced Materials, Advanced Energy Materials, Nano-Micro Letters, and Journal of Physical Chemistry Letters. His publications demonstrate both depth and diversity, covering experimental studies and theoretical analyses of energy materials. As a corresponding author on multiple papers, he has taken a leading role in shaping research directions and mentoring junior researchers. His work on interface engineering, lithium-ion transport, and material stability is widely referenced and is contributing to shaping the current and future landscape of solid-state battery research.

Academic Citations

Dr. Song’s academic output has garnered significant citations, reflecting the relevance and scientific merit of his work within the global research community. His papers are frequently cited in studies related to solid-state electrolytes, lithium dendrite suppression, and battery interface modeling. These citations not only reflect scholarly recognition but also indicate that his research findings are being used as a foundation for further innovations in battery science and materials engineering.

Technical Skills

Dr. Song possesses a wide range of technical skills, including the synthesis and characterization of solid electrolytes, electrochemical testing of battery cells, and materials analysis through advanced techniques such as XRD, SEM, TEM, and EIS. He is adept in handling both experimental design and data interpretation, making him a versatile and efficient materials scientist. His work also includes the use of simulation tools to understand energy band behavior and ion transport mechanisms at the micro and nano scales.

Teaching Experience

In his current academic role, Dr. Song contributes to the education and mentorship of undergraduate and graduate students in energy materials, electrochemistry, and battery technologies. He plays an active role in curriculum development, laboratory instruction, and academic supervision. Through lectures and hands-on research training, he nurtures the next generation of scientists and engineers, fostering critical thinking and innovation in the classroom and laboratory settings alike.

Legacy and Future Contributions

Dr. Song’s research trajectory positions him as a rising leader in the field of solid-state battery technology. His multi-faceted work on material systems and interfacial phenomena is not only advancing current knowledge but is also paving the way for future breakthroughs in sustainable energy storage. Moving forward, he is expected to contribute significantly to the industrialization of solid-state batteries, engage in international collaborations, and lead transformative research initiatives that align with global clean energy goals. His dedication to impactful science, education, and innovation ensures a lasting legacy in both academia and industry.

Notable Publications

  • Chemical and Electrochemical Failure Processes in the Interface Reaction between LATP and Lithium Metal Anode
    Authors: Yuchen Qi, Yongli Song
    Journal: Journal of Alloys and Compounds
    Year: 2025

  • 1D ZrCl₄ Matrices for Enhanced Ion Transport in Glassy Chloride Electrolytes
    Authors: Yongli Song, et al.
    Journal: Advanced Energy Materials
    Year: 2025

  • Revealing the Short-Circuiting Mechanism of Garnet-Based Solid State Electrolyte
    Authors: Yongli Song, et al.
    Journal: Advanced Energy Materials
    Year: 2019

  • Tailoring Interfacial Structures to Regulate Carrier Transport in Solid-State Batteries
    Authors: Zhikang Deng, Yongli Song, et al.
    Journal: Advanced Materials
    Year: 2024

  • Insights into the Interfacial Degradation of High-Voltage All-Solid-State Lithium Batteries
    Authors: Jiawen Li, Yongli Song, et al.
    Journal: Nano-Micro Letters
    Year: 2022

Conclusion

Dr. Yongli Song exemplifies a dynamic and impactful researcher whose work spans fundamental science and applied energy technologies. Through a well-defined focus on solid-state electrolytes and a consistent record of high-quality publications, he has contributed meaningfully to the advancement of battery materials science. His blend of academic rigor, professional experience, and research innovation makes him a vital asset to the scientific community and a strong candidate for recognition in the field of energy research.