Li Song | Energy Materials | Best Researcher Award

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Assoc. Prof. Dr. Li Song | Energy Materials | Best Researcher Award

Deputy dean from Nanjing University of Information Science and Technology, China

Dr. Li Song is an accomplished Associate Professor at the School of Environmental Science and Engineering, Nanjing University of Information Science & Technology. With a specialized focus on carbon-based materials for clean energy conversion and storage, Dr. Song’s academic journey reflects a deep commitment to innovative research in materials science and sustainable energy technologies. Her extensive research experience includes prestigious international collaborations and projects supported by leading Chinese and provincial scientific foundations. Her work revolves around designing advanced carbon-based catalytic systems, aiming for improved energy efficiency and sustainability. Having published widely and participated in several key research programs, she is recognized for her interdisciplinary approach and ability to bridge theoretical design with practical application in fuel cells, metal-air batteries, and other green energy devices. Her background includes training and research at globally respected institutions like Case Western Reserve University and SUNY Buffalo, where she collaborated with world-leading experts in electrocatalysis and material engineering. With an eye toward real-world applications, Dr. Song continues to explore the intersection of nanotechnology, catalysis, and clean energy, positioning herself as a future leader in sustainable materials research.

Professional Profile

Education

Dr. Li Song’s academic credentials reflect her dedication to the advancement of materials science, particularly in the realm of clean energy. She earned her Ph.D. in Materials Physics and Chemistry from Nanjing University of Aeronautics and Astronautics in June 2020 under the mentorship of Prof. Jianping He. Her doctoral work focused on the design of advanced carbon-based catalytic materials for green energy applications. During her Ph.D. studies, she gained valuable international exposure through a joint Ph.D. program with Case Western Reserve University (USA), where she worked under the guidance of Prof. Liming Dai, a globally recognized expert in macromolecular science and engineering. This collaboration significantly enriched her expertise in carbon nanomaterials and energy storage systems. Additionally, Dr. Song expanded her research experience as a visiting scholar at SUNY Buffalo, working with Prof. Gang Wu on highly active catalysts for fuel cells. Her academic foundation also includes dual bachelor’s degrees in Metal Material Engineering and English from Nanchang Hangkong University, completed in 2013. This multidisciplinary background not only equipped her with strong technical skills but also enhanced her communication and collaboration abilities, essential for her global research engagements and academic contributions.

Professional Experience

Dr. Li Song has cultivated a robust academic and research career rooted in innovation and international collaboration. She began her professional journey at Nanjing University of Information Science & Technology (NUIST) in 2020, initially as a Lecturer and later advancing to Associate Professor. Her current role involves leading cutting-edge research in carbon-based materials for energy conversion and storage, a field at the forefront of clean energy technology. At NUIST, she has played a central role in developing new materials and catalytic systems, contributing to the university’s reputation for advanced environmental science research. Beyond her responsibilities at NUIST, Dr. Song has gained significant global research experience. Between 2017 and 2019, she served as a joint Ph.D. researcher at Case Western Reserve University, USA, and previously as a visiting scholar at SUNY Buffalo, where she conducted high-impact research on fuel cell catalysts. These international appointments allowed her to work with leading figures in the field and exposed her to diverse, multidisciplinary methodologies. Through her academic appointments, Dr. Song has developed a deep expertise in materials science, catalysis, and sustainable energy applications, which she continues to apply in mentoring students, managing research projects, and publishing innovative scientific work.

Research Interests

Dr. Li Song’s research interests lie at the dynamic intersection of materials science, nanotechnology, and sustainable energy systems. She is particularly focused on the rational design and fabrication of carbon-based catalytic materials for clean energy conversion and storage. Her work emphasizes the creation of efficient, durable catalysts that can be implemented in devices such as fuel cells, metal-air batteries, and electrolyzers. Central to her research is the development of intrinsic active sites in carbon materials through heteroatom doping, structural modification, and topological defect engineering at the atomic scale. She is also interested in optimizing the mesoscopic structure of these materials—such as one-dimensional carbon fibers, carbon nanotubes, and three-dimensional porous frameworks—to enhance mass transfer and overall catalytic efficiency. Furthermore, Dr. Song explores the fundamental catalytic mechanisms governing these systems, aiming to correlate composition and structural features with functional performance. Her long-term goal is to design scalable, high-performance energy devices with real-world applications, thus contributing to the broader shift toward cleaner, more sustainable technologies. Her interdisciplinary approach, combining chemistry, materials physics, and engineering, positions her at the forefront of energy materials research, with a clear vision for addressing contemporary environmental and energy challenges.

Research Skills

Dr. Li Song possesses a diverse and advanced skill set that supports her innovative research in energy materials. She specializes in the design and synthesis of carbon-based nanomaterials with enhanced electrocatalytic properties. Her technical expertise includes heteroatom doping, heterostructure fabrication, and defect engineering to optimize catalytic activity at the atomic level. She is highly proficient in constructing mesoscopic architectures—such as carbon fibers, nanotubes, nanosheets, and core-shell structures—which facilitate mass transfer and improve diffusion rates in catalytic systems. Dr. Song is also adept at using state-of-the-art characterization techniques, including electron microscopy, spectroscopy, and electrochemical analysis, to investigate material properties and evaluate catalytic performance. She has strong competencies in project management and proposal writing, as evidenced by her leadership in multiple grant-funded research projects. Moreover, her international collaborations have equipped her with excellent cross-cultural communication skills and a global perspective on scientific problem-solving. Her background in English, paired with technical proficiency, further enhances her ability to disseminate research through publications, presentations, and academic exchanges. These well-rounded research capabilities make Dr. Song not only a leading scientist in her domain but also a capable mentor and team leader in multidisciplinary projects focused on sustainable technologies.

Awards and Honors

Dr. Li Song’s academic and research excellence is reflected in the prestigious grants and competitive research programs she has secured. She is the principal investigator of several notable projects, including the Natural Science Foundation of Jiangsu Province-funded initiative on single-atom oxygen reduction catalysts (BK20210651, 2021–2024). This project demonstrates her leadership and innovative contributions in the development of highly efficient electrocatalysts. Earlier in her academic career, she led research supported by the Doctoral Thesis Innovation and Excellence Foundation of Nanjing University of Aeronautics and Astronautics, where she explored the use of metal-organic frameworks in bifunctional electrocatalysis (2017–2018). Her work has also been recognized through the Graduate Research Innovation Plan of Jiangsu Province. Additionally, she contributed to a National Natural Science Foundation of China project (11575084) focused on advanced composite coatings and radiation resistance, showcasing her versatility in tackling both theoretical and application-driven challenges. These honors highlight her growing reputation as a researcher capable of securing funding and producing impactful work. Her ability to manage complex scientific inquiries while delivering meaningful contributions to the energy materials field makes her a strong candidate for further recognition and collaboration on both national and international levels.

Conclusion

In conclusion, Dr. Li Song stands out as a highly promising researcher in the field of clean energy materials. Her deep expertise in the synthesis and structural engineering of carbon-based catalysts places her at the cutting edge of sustainable energy research. Through her academic achievements, international collaborations, and leadership in grant-funded projects, she has consistently demonstrated the capacity to bridge theoretical innovations with practical applications. Dr. Song’s focus on the rational design of electrocatalysts, exploration of catalytic mechanisms, and development of scalable energy devices reflects a holistic research philosophy aligned with global sustainability goals. Her interdisciplinary skill set, coupled with strong academic training and a global perspective, equips her to make long-lasting contributions to both science and society. Furthermore, her success in securing competitive research funding and publishing in relevant areas underlines her scientific rigor and professional maturity. As clean energy becomes increasingly vital to global development, researchers like Dr. Song—who combine creativity, technical excellence, and collaborative spirit—will play an essential role. Her trajectory suggests continued innovation and leadership, positioning her as an ideal candidate for future honors and elevated academic positions in the field of materials science and environmental engineering.

Publications Top Notes

  1. Title: In-situ metallic Ag-doping of CFx cathode: An efficient strategy to solve the problems of high resistivity and unavoidable polarization
    Authors: J. Xu, Jianwen; H. Luo, Hao; J. Ma, Jun; L. Song, Li; Y. Jin, Yachao
    Year: 2025
    Journal: Electrochimica Acta

  2. Title: Constructing ZnS@hard carbon nanosheets for high-performance and long-cycle sodium-ion batteries
    Authors: H. Zhang, Huan; F. Yuan, Fengzhou; M. Zhang, Mingdao; H. Zheng, Hegen
    Year: 2025
    Journal: Chemical Engineering Journal

  3. Title: Heteroatom Doping Modulates the Electronic Environment of Bi for Efficient Electroreduction of CO2 to Formic Acid
    Authors: S. Zhao, Sirui; H. Zhou, Heng; D. Cao, Dengfeng; L. Song, Li; S. Chen, Shuangming
    Year: 2025
    Journal: Chemical Research in Chinese Universities

  4. Title: Sulfate Oxyanion Steered d-Orbital Electronic State of Nickel-Iron Nanoalloy for Boosting Electrocatalytic Performance
    Authors: Y. Jin, Yachao; X. Qu, Xijun; Z. Zhou, Zihao; W. Ma, Wenqiang; M. Zhang, Mingdao
    Year: 2025
    Journal: Small

  5. Title: Tailored Heterogeneous Catalysts via Space-Confined Engineering for Efficient Electrocatalytic Oxygen Evolution
    Authors: C. Wu, Chenxiao; C. Liu, Chuang; A. Gao, Ang; H. Guo, Haizhong; L. Gu, Lin
    Year: 2025
    Journal: Advanced Functional Materials

  6. Title: Preparation of p-type Fe₂O₃ nanoarray and its performance as photocathode for photoelectrochemical water splitting
    Authors: X. Fan, Xiaoli; F. Zhu, Fei; Z. Wang, Zeyi; J. He, Jianping; T. Wang, Tao
    Year: 2025
    Journal: Frontiers in Chemistry

  7. Title: Facile and Rapid Synthesis of Ultra-Low-Loading Pt-Based Catalyst Boosting Electrocatalytic Hydrogen Production
    Authors: W. Zhai, Wenjie; J. Wang, Jiayi; M. Zhang, Mingdao; L. Song, Li
    Year: 2025
    Journal: ChemPlusChem

  8. Title: A Method of Efficiently Regenerating Waste LiFePO₄ Cathode Material after Air Firing Treatment
    Authors: J. Ma, Jun; Z. Xu, Ziyang; T. Yao, Tianshun; L. Song, Li; M. Zhang, Mingdao
    Year: 2024
    Journal: ACS Applied Materials and Interfaces

  9. Title: Sustainable regeneration of a spent layered lithium nickel cobalt manganese oxide cathode from a scrapped lithium-ion battery
    Authors: Y. Jin, Yachao; X. Qu, Xijun; L. Ju, Liyun; L. Song, Li; M. Zhang, Mingdao
    Year: 2024
    Citations: 1

  10. Title: ZIF-derived “cocoon”-like in-situ Zn/N-doped carbon as high-capacity anodes for Li/Na-ion batteries
    Authors: F. Yuan, Fengzhou; Z. Chen, Zhe; H. Zhang, Huan; L. Song, Li; M. Zhang, Mingdao
    Year: 2024
    Journal: Colloids and Surfaces A: Physicochemical and Engineering Aspects

 

 

KUN LUO | Energy Chemistry | Best Researcher Award

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Prof. Dr. KUN LUO | Energy Chemistry | Best Researcher Award

Professor from Tianjin University of Technology, China

Prof. Dr. Kun Luo is a distinguished researcher and academic in the field of energy materials and inorganic chemistry, with a robust background in materials science and engineering. With over two decades of experience in research and academia, he has made significant contributions to the advancement of battery technologies and sustainable energy materials. Dr. Luo is currently a professor at Tianjin University of Technology in China, where he leads innovative research in energy storage and materials synthesis. He completed his PhD in Inorganic Chemistry at the University of Oxford and has held prominent research positions at the University of St Andrews and Oxford, reflecting a solid international academic background. His research has been published in prestigious journals such as Nature Chemistry, Nano Letters, ACS Sustainable Chemistry & Engineering, and Journal of the American Chemical Society, demonstrating a high impact and relevance in the scientific community. Prof. Luo’s work focuses on novel electrode materials, redox chemistry, and the development of efficient, durable battery systems. His contributions are not only academic but also highly practical, supporting the global transition to sustainable energy. With a rich portfolio of publications and consistent research productivity, Prof. Luo is an exemplary candidate for the Best Researcher Award.

Professional Profile

Education

Prof. Dr. Kun Luo has a distinguished educational background that has laid a strong foundation for his scientific career. He began his academic journey at Zhejiang University, China, where he earned both his Bachelor’s and Master’s degrees in Materials Science and Engineering between 2003 and 2010. These formative years provided him with extensive knowledge of materials synthesis, characterization, and engineering principles. Recognized for his academic excellence, he pursued doctoral studies at the prestigious University of Oxford, where he received his PhD in Inorganic Chemistry in 2013. During his PhD, he focused on the synthesis and structural characterization of complex transition metal oxides, which would later become a cornerstone of his research expertise in energy materials. The combination of his background in materials engineering and deep chemical insight allowed him to approach energy problems with a unique interdisciplinary perspective. His education at institutions known for research rigor and innovation prepared him to tackle advanced scientific problems and train future generations of researchers. The academic diversity and international exposure in both Chinese and British universities gave him a global outlook and an adaptable approach to collaborative research and teaching, making his educational profile both versatile and elite.

Professional Experience

Prof. Dr. Kun Luo has accumulated an impressive array of professional experiences across some of the world’s leading academic institutions. Following his PhD at the University of Oxford, he began his postdoctoral research at the University of St Andrews from 2013 to 2014, where he deepened his expertise in solid-state chemistry and advanced materials. He then returned to Oxford as a postdoctoral researcher from 2014 to 2017, contributing to cutting-edge projects on battery materials and redox chemistry. In 2018, he assumed a professorial role at Nankai University in Tianjin, China, where he led research in inorganic chemistry until 2022. During this period, his research group focused on developing high-performance electrode materials and exploring the fundamental science behind electrochemical energy storage. In 2022, he joined Tianjin University of Technology as a full professor in the School of Materials Science and Engineering. Throughout his career, Prof. Luo has demonstrated a consistent trajectory of advancement, reflecting both his research excellence and leadership capabilities. His academic appointments have allowed him to secure substantial research funding, supervise graduate students, and collaborate with global scholars. These roles underscore his commitment to both research and education, firmly establishing him as a leader in the field of energy materials.

Research Interests

Prof. Dr. Kun Luo’s research interests lie at the intersection of energy storage, inorganic chemistry, and materials engineering. His primary focus is on the development and optimization of advanced energy materials, particularly for battery technologies. He is deeply engaged in designing novel electrode materials, such as lithium-ion and sodium-ion battery components, which exhibit superior capacity, stability, and charge-discharge performance. His work explores solid-state reactions, redox mechanisms, and structural evolution during electrochemical cycling. He also investigates the role of oxygen and anion redox processes in transition metal oxide electrodes to improve energy density and safety. Another vital area of interest is the integration of sustainable practices into energy materials design, such as using abundant and environmentally benign elements. Prof. Luo’s research extends to hydrogen storage materials, where he examines reaction kinetics and thermodynamics to improve storage efficiency. His interdisciplinary approach blends chemistry, materials science, and engineering, enabling practical applications in renewable energy and sustainable technology development. By addressing both theoretical and applied challenges, his research contributes significantly to global efforts toward clean energy solutions. His work is at the forefront of next-generation battery technologies, making his research highly relevant for industries aiming to revolutionize portable and large-scale energy systems.

Research Skills

Prof. Dr. Kun Luo possesses a wide array of advanced research skills that enable him to conduct cutting-edge investigations in energy materials and inorganic chemistry. He is proficient in the synthesis of complex oxide materials, employing methods such as solid-state reactions, hydrothermal synthesis, and topochemical modifications. His expertise extends to structural characterization using techniques like X-ray diffraction (XRD), neutron diffraction, transmission electron microscopy (TEM), and pair distribution function (PDF) analysis, allowing precise determination of crystallographic and local atomic structures. Dr. Luo is also adept in electrochemical characterization, including cyclic voltammetry, galvanostatic charge-discharge tests, and electrochemical impedance spectroscopy (EIS), which he uses to assess battery performance and reaction mechanisms. He is highly experienced in analyzing redox processes, particularly oxygen redox activity, and understanding charge compensation phenomena in transition metal oxides. Furthermore, his familiarity with computational modeling and thermodynamic analysis enhances his ability to predict and explain material behavior under various conditions. His interdisciplinary skill set bridges chemistry, materials science, and engineering, enabling him to tackle complex challenges in sustainable energy storage. These skills not only underscore his scientific depth but also his adaptability to evolving research frontiers, reinforcing his status as a top-tier researcher in energy materials.

Awards and Honors

While Prof. Dr. Kun Luo’s curriculum vitae does not explicitly list awards and honors, his scholarly impact and publication record strongly suggest a career marked by distinction and recognition in the scientific community. His research has been featured in some of the most prestigious and high-impact journals in materials science and chemistry, such as Nature Chemistry, Nano Letters, Journal of the American Chemical Society, and ACS Sustainable Chemistry & Engineering. The consistent publication of impactful work over the years highlights the academic community’s acknowledgment of his research quality and relevance. Moreover, he has served as a peer reviewer for reputable journals, including ACS Applied Energy Materials, further reflecting his standing as a trusted expert in his field. His appointments at globally respected institutions like the University of Oxford and Nankai University also signify academic recognition and trust in his abilities. Although not explicitly detailed, it is reasonable to infer that he has been the recipient of internal and collaborative research funding, enabling him to lead and execute high-level projects. These forms of implicit recognition, combined with his citation impact and leadership roles, indicate that Prof. Luo is highly esteemed and likely to be honored further as his research continues to influence the energy materials field.

Conclusion

Prof. Dr. Kun Luo exemplifies excellence in research, academic leadership, and scientific innovation. With a robust educational background, extensive professional experience at top-tier institutions, and a prolific research portfolio, he stands out as a leading figure in the field of energy materials. His pioneering contributions to battery materials, inorganic chemistry, and sustainable energy technologies have advanced both theoretical understanding and real-world applications. Dr. Luo’s interdisciplinary approach, integrating chemistry and engineering, demonstrates his capacity to address pressing global challenges such as clean energy storage. His research not only contributes to academic progress but also holds significant potential for industrial and environmental impact. Furthermore, his mentoring of young scientists and involvement in peer review activities underline his commitment to the advancement of science and education. Although his formal accolades may not be extensively documented, his publication history and professional trajectory clearly establish him as a thought leader in his domain. Given his consistent research output, global academic involvement, and deep technical expertise, Prof. Dr. Kun Luo is an outstanding candidate for the Best Researcher Award. His profile embodies the values of innovation, integrity, and excellence that such an honor is intended to celebrate.

Publications Top Notes

  • Title: Suppressing staircase-like electrochemical profile induced by P–O transition by solid-solution reaction with continuous structural evolution in layered Na-ion battery cathode
    Authors: Kun Luo, Ming Chen, Mengdan Tian, Wenhui Li, Yang Jiang, Zhihao Yuan
    Year: 2023

  • Title: High-Capacity Anode Material for Lithium-Ion Batteries with a Core–Shell NiFe₂O₄/Reduced Graphene Oxide Heterostructure
    Authors: Chang Liu, Tong Zhang, Lixin Cao, Kun Luo
    Year: 2021

  • Title: Charge-compensation in 3d-transition-metal-oxide intercalation cathodes through the generation of localized electron holes on oxygen
    Authors: Niccolo Guerrini, Liyu Jin, Juan G. Lozano, Kun Luo, Adam Sobkowiak, Kazuki Tsuruta, Felix Massel, Laurent-C. Duda, Matthew R. Roberts, Peter Bruce
    Year: 2020

  • Title: Oxygen redox chemistry without excess alkali-metal ions in Na₂/₃[Mg₀.₂₈Mn₀.₇₂]O₂
    Authors: Urmimala Maitra, Robert A. House, James W. Somerville, Nuria Tapia-Ruiz, Juan G. Lozano, Niccoló Guerrini, Rong Hao, Kun Luo, Liyu Jin, Miguel A. Pérez-Osorio et al.
    Year: 2018

  • Title: Identifying the local structural units in La₀.₅Ba₀.₅MnO₂.₅ and BaY₀.₂₅Fe₀.₇₅O₂.₅ through the neutron pair distribution function
    Authors: Graham King, Kun Luo, John Greedan, Michael Hayward
    Year: 2017

  • Title: One-Pot Synthesis of Lithium-Rich Cathode Material with Hierarchical Morphology
    Authors: Kun Luo, Matthew R. Roberts, Rong Hao, Niccoló Guerrini, Emanuela Liberti, Christopher S. Allen, Angus I. Kirkland, Peter G. Bruce
    Year: 2016

  • Title: Anion Redox Chemistry in the Cobalt Free 3d Transition Metal Oxide Intercalation Electrode Li[Li₀.₂Ni₀.₂Mn₀.₆]O₂
    Authors: Kun Luo, Matthew R. Roberts, Niccoló Guerrini, Nuria Tapia-Ruiz, Rong Hao, Felix Massel, David M. Pickup, Silvia Ramos, Yi-Sheng Liu, Jinghua Guo et al.
    Year: 2016

  • Title: Charge-compensation in 3d-transition-metal-oxide intercalation cathodes through the generation of localized electron holes on oxygen
    Authors: Kun Luo, Matthew R. Roberts, Rong Hao, Niccoló Guerrini, David M. Pickup, Yi-Sheng Liu, Kristina Edström, Jinghua Guo, Alan V. Chadwick, Laurent C. Duda et al.
    Year: 2016

  • Title: Ca₂Cr₀.₅Ga₁.₅O₅—An extremely redox-stable brownmillerite phase
    Authors: Kun Luo, Midori Amano Patino, Michael A. Hayward
    Year: 2015

  • Title: Stoichiometry dependent Co³⁺ spin-state in LaₓSr₂₋ₓCoGaO₅₊δ brownmillerite phases
    Authors: Kun Luo, Michael A. Hayward
    Year: 2014