Chihyun Hwang | Energy Sustainability | Best Researcher Award

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Dr. Chihyun Hwang | Energy Sustainability | Best Researcher Award

Principle at Koreal Electronics Technology Institute | South Korea

Dr. Chihyun Hwang is a distinguished energy scientist and Senior Researcher at the Korea Electronics Technology Institute (KETI), specializing in next-generation electrochemical energy storage systems. His expertise spans lithium-ion, sodium-ion, zinc-ion, and all-solid-state batteries, with particular emphasis on molecular binder design, nanostructured anodeless materials, and in-situ electrochemical analysis. Over the years, he has developed an outstanding research profile, contributing significantly to advancing energy technologies that support high-density, durable, and safe energy storage solutions for electric vehicles and renewable energy systems. With an H-index of 22 and nearly 60 published papers in prestigious journals such as Advanced Energy Materials, Advanced Functional Materials, and Angewandte Chemie, he has demonstrated both academic excellence and industry relevance. His work has frequently addressed critical issues in interface stability, electrode architecture, and electrochemical reversibility, ensuring long-term performance and scalability of energy storage devices. Beyond publications, Dr. Hwang actively contributes to professional communities, serving as Academic Director of the Korean Battery Society. His research leadership, supported by national and international collaborations, has positioned him as a vital contributor to the global battery research community, dedicated to enabling sustainable and high-performance energy technologies for the future.

Professional Profile

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Education

Dr. Chihyun Hwang pursued a rigorous academic path that laid the foundation for his career in energy storage research. He earned his Bachelor of Science in Fiber Engineering from Inha University, where he developed a strong materials science background. Motivated by the potential of energy technologies, he advanced to doctoral studies at the Ulsan National Institute of Science and Technology (UNIST), completing his Ph.D. in Energy Engineering under the mentorship of Professor Hyun-Kon Song. His doctoral research, titled Designing Molecular Structures of Polymeric Binders for Alloying-Based Anodes, reflected his early focus on electrochemical materials engineering and binder chemistry. The project involved designing and optimizing polymer binders to enhance electrode reversibility and stability, especially for high-capacity alloying anode systems such as silicon and antimony. This work gave him critical expertise in molecular design, electrochemical kinetics, and the durability of next-generation battery systems. His academic training was further enriched through exposure to interdisciplinary studies in chemical engineering, materials processing, and nanotechnology. Collectively, his education equipped him with both theoretical depth and experimental versatility, enabling him to address fundamental challenges in modern battery science while preparing him for a highly impactful international research career.

Professional Experience

Dr. Chihyun Hwang’s professional journey demonstrates a consistent trajectory of leadership and innovation in advanced energy storage. He has served as Senior Researcher at the Advanced Batteries Research Center of KETI, where he leads multiple large-scale projects on lithium metal, sodium-ion, and solid-state batteries. He was previously a Research Professor at UNIST, focusing on energy and chemical engineering, bridging academia and industry in battery innovation. Before that, he broadened his international exposure as a Postdoctoral Fellow in the research group of Prof. Nian Liu at the Georgia Institute of Technology, investigating zinc-ion and solid-state battery chemistries. Prior to his U.S. experience, he worked as a Postdoctoral Researcher in Prof. Hyun-Kon Song’s group at UNIST, extending his doctoral research into industrially viable energy storage solutions. At KETI, Dr. Hwang plays a critical role in projects developing digital twin infrastructures for battery manufacturing, high-energy solid-state batteries, and safe sodium-ion systems. His career reflects an integration of academic rigor, postdoctoral innovation, and applied industrial research, with a strong emphasis on multidisciplinary collaboration. This combination highlights his ability to translate laboratory advances into scalable technologies, essential for global energy transition initiatives.

Research Interest

Dr. Chihyun Hwang’s research interests span a wide spectrum of next-generation energy storage technologies, emphasizing fundamental innovation and practical application. A major focus is all-solid-state batteries, where he works on designing polymeric binders, nanostructured anodeless materials, and interfacial stabilizers to improve energy density and long-term cycling. He also explores large-scale bipolar stacking strategies to enable commercialization. His second research stream involves sodium-ion batteries, particularly mitigating reactive oxygen species through surface doping and additive engineering for stable high-voltage cathodes. Another growing area is zinc-ion batteries, where his work includes developing single-crystalline zinc anodes, electrolyte systems, and protective interfacial layers that enhance cycling stability and suppress dendritic growth. A distinctive strength of his research lies in in-situ electrochemical analysis, employing advanced techniques such as Raman microscopy, differential electrochemical mass spectrometry, and impedance spectroscopy to elucidate reaction mechanisms. These methods provide molecular-level insights into degradation and reversibility, accelerating the design of more robust systems. Collectively, his research aims to develop high-energy-density, safe, and durable electrochemical storage devices for electric mobility and renewable integration. His interests integrate theoretical understanding, nanomaterials design, and scalable processing, establishing him as a leading figure in the quest for sustainable battery technologies.

Research Skills

Dr. Chihyun Hwang possesses a diverse and highly specialized skill set that underpins his success in energy storage research. He is an expert in molecular and polymer design, particularly for binders that enhance electrode kinetics and mechanical resilience. His skills in nanostructure engineering allow him to create novel anodeless materials and functional electrode architectures that optimize charge transport and suppress failure mechanisms. A significant technical strength lies in his command of in-situ characterization techniques, including Raman microscopy, electrochemical impedance spectroscopy, and differential electrochemical mass spectrometry, which provide real-time insights into electrochemical reactions and interfacial dynamics. He is also highly experienced in solid-state battery fabrication and analysis, enabling him to evaluate interface stability and optimize electrolyte formulations. His expertise extends to computational and analytical methods, which he uses to model battery reactions and validate experimental findings. Beyond laboratory techniques, Dr. Hwang demonstrates strong project management skills, having coordinated multi-institutional and industry-supported initiatives. His ability to integrate materials synthesis, device engineering, and mechanistic analysis allows him to approach research challenges holistically. These combined skills make him not only a prolific researcher but also a leader capable of bridging science, engineering, and technology development in advanced energy systems.

Awards and Honors

Dr. Chihyun Hwang’s contributions to energy research have been recognized through prestigious awards and leadership roles that highlight both his scientific excellence and professional impact. He was elected Academic Director of the Korean Battery Society, underscoring his standing as a leading voice in the national research community. He also received the Award Certificate of Chungbuk Governor, reflecting regional acknowledgment of his technological contributions. He was honored with the highly competitive Sejong Science Fellowship (NRF), awarded to exceptional early-career researchers in Korea. This fellowship supported his independent research initiatives and accelerated his trajectory in advanced battery innovation. In addition to these distinctions, Dr. Hwang has consistently been invited to deliver presentations at international conferences, including meetings of the Materials Research Society, Electrochemical Society, and Korean Battery Society. His invited talks and presentations demonstrate global recognition of his expertise in zinc-ion, sodium-ion, and solid-state batteries. Collectively, these awards and honors not only validate his scientific contributions but also highlight his leadership potential in shaping Korea’s and the world’s energy technology landscape. His recognitions underscore his dual role as a pioneering researcher and influential academic contributor.

Publications Top Notes

Title: Gel/solid polymer electrolytes characterized by in situ gelation or polymerization for electrochemical energy systems
Year: 2019
Citation: 304

Title: Self‐assembling films of covalent organic frameworks enable long‐term, efficient cycling of zinc‐ion batteries
Year: 2021
Citation: 188

Title: Mechanical mismatch-driven rippling in carbon-coated silicon sheets for stress-resilient battery anodes
Year: 2018
Citation: 138

Title: Folding graphene film yields high areal energy storage in lithium-ion batteries
Year: 2018
Citation: 122

Title: An antiaging electrolyte additive for high‐energy‐density lithium‐ion batteries
Year: 2020
Citation: 83

Conclusion

Dr. Chihyun Hwang exemplifies the profile of a modern applied scientist, integrating deep academic training, cutting-edge research, and practical innovation in the field of advanced batteries. With a career spanning prestigious institutions in Korea and the United States, he has built a strong reputation for addressing critical challenges in electrochemical energy storage through creative design and rigorous analysis. His more than 50 publications, combined with international collaborations and leadership in professional societies, mark him as both a thought leader and a collaborative innovator. His work consistently bridges the gap between theory and application, from molecular design of binders to the development of high-energy solid-state and sodium-ion systems. Recognition through fellowships, awards, and professional leadership further reflects his excellence and influence in the scientific community. Looking forward, Dr. Hwang is well-positioned to drive transformative advances in sustainable energy technologies, particularly in developing safer, higher-density, and more durable batteries for electric mobility and renewable integration. His career embodies a commitment to excellence, innovation, and impact, making him not only a respected researcher but also a vital contributor to the global transition toward sustainable energy solutions.

Yu-Xin Miao | Environmental Science | Best Researcher Award

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Assoc. Prof. Dr. Yu-Xin Miao | Environmental Science | Best Researcher Award

Teacher at Shenyang Normal University | China

Dr. Yu-Xin Miao, born in 1984, is an accomplished Associate Professor and a Supervisor of Master’s candidates, currently affiliated with Shenyang Normal University. With a Ph.D. from the State Key Laboratory of Fine Chemicals, Dalian University of Technology, he has made significant strides in the field of energy and environmental catalysis. Dr. Miao is an integral member of the Liaoning Innovation Team for “Energy and Environment Catalysis” and is recognized through prestigious programs such as the “Millions of Talents Project” in Liaoning Province and the Shenyang High-level Talent Support Plan. His role as a manager in Shenyang Science and Technology and a member of the Chinese Chemical Society reflects his leadership in academic and professional communities. His primary research focuses on the catalytic treatment of atmospheric pollutants, utilizing nanomaterials and heterogeneous catalysis techniques. With over 30 peer-reviewed publications in leading journals like Chinese Journal of Catalysis, Chemical Communications, and New Journal of Chemistry, as well as three patents to his name, Dr. Miao has demonstrated a strong track record of innovation. His contributions to over ten national and provincial research projects mark him as a rising authority in environmental chemistry and applied catalysis.

Professional Profile

Scopus | ORCID 

Education

Dr. Yu-Xin Miao received his doctoral degree in 2016 from the State Key Laboratory of Fine Chemicals at the prestigious Dalian University of Technology. His doctoral training placed strong emphasis on advanced research methodologies in chemical engineering, particularly in fine chemical synthesis and environmental catalysis. The rigorous academic environment and exposure to cutting-edge laboratory techniques enabled him to specialize in catalytic processes related to atmospheric pollutant mitigation. Prior to his Ph.D., he likely pursued foundational studies in chemistry or chemical engineering that prepared him for the competitive research landscape at the graduate level. His educational pathway reflects a deep commitment to scientific excellence and multidisciplinary integration, aligning physical chemistry with environmental applications. Dr. Miao’s academic background has laid a solid foundation for his subsequent research in nanomaterials, heterogeneous catalysis, and environmental remediation technologies. Furthermore, his education has empowered him with a comprehensive understanding of both theoretical and experimental aspects of chemical science, which he now leverages to supervise graduate students and lead funded research projects. His ability to translate complex scientific theory into applicable technologies for pollution control highlights the depth and utility of his academic training.

Professional Experience

Dr. Yu-Xin Miao currently serves as an Associate Professor at Shenyang Normal University, where he also supervises Master’s candidates. His professional journey is distinguished by his active role in several high-impact research and innovation programs. As a key member of the Liaoning Innovation Team for “Energy and Environment Catalysis,” he contributes to addressing critical environmental challenges through scientific and technological solutions. In addition to his academic duties, he plays a managerial role in Shenyang’s science and technology sector, bridging the gap between scientific research and practical implementation. He has led over ten research projects funded by prestigious institutions such as the National Natural Science Foundation of China and the Liaoning Provincial Natural Science Foundation. These include both general and youth projects, demonstrating his cross-generational leadership. Dr. Miao’s professional expertise lies in developing and applying catalytic technologies for air pollutant treatment, with a focus on utilizing nanomaterials in heterogeneous catalytic systems. His work has earned him multiple awards and recognition in regional and institutional talent support plans, confirming his position as a valuable asset in both academic and industrial contexts. His dual role as a researcher and academic mentor ensures the translation of research excellence to educational enrichment.

Research Interest

Dr. Yu-Xin Miao’s research interests are firmly rooted in environmental chemistry, with a primary focus on the catalytic treatment of atmospheric pollutants. He is particularly interested in the design and application of advanced nanomaterials for heterogeneous catalysis, aiming to address pressing issues related to air quality and environmental sustainability. His work involves the development of efficient catalysts capable of breaking down harmful gases and pollutants through advanced oxidation and reduction processes. Dr. Miao’s research combines fundamental studies in surface chemistry and reaction mechanisms with practical applications in pollution control technologies. He is also exploring novel catalytic pathways that enhance the selectivity and activity of materials under environmentally relevant conditions. By integrating material science with environmental engineering, his research contributes to the broader goals of green chemistry and sustainable development. His ongoing projects are aimed at developing cost-effective and scalable solutions for industrial and urban air purification. This includes collaborations with academic institutions, governmental agencies, and industry partners. Dr. Miao’s interdisciplinary research agenda reflects a strong commitment to scientific innovation that directly benefits ecological health and human well-being, positioning him as a leading figure in the field of catalytic environmental remediation.

Research Skills

Dr. Yu-Xin Miao possesses a comprehensive skill set in chemical engineering and environmental catalysis, particularly in the synthesis, characterization, and application of nanomaterials. He is adept at employing a range of analytical techniques such as X-ray diffraction (XRD), transmission electron microscopy (TEM), scanning electron microscopy (SEM), and X-ray photoelectron spectroscopy (XPS) to elucidate the structure and performance of catalytic materials. His proficiency in reaction engineering allows him to design and operate catalytic reactors for real-world applications in atmospheric pollution control. Dr. Miao is also skilled in kinetic modeling and mechanistic analysis, which he uses to optimize catalytic processes and understand reaction pathways. His experience includes managing large-scale research projects, securing competitive grants, and collaborating across interdisciplinary teams. Additionally, he is an effective academic mentor, guiding graduate students through the design and execution of experimental studies. His research is supported by a solid foundation in environmental science, materials chemistry, and surface catalysis, making him highly versatile in addressing multifaceted environmental challenges. Dr. Miao’s ability to integrate theoretical knowledge with practical applications enhances the relevance and impact of his work, and his technical and project management skills continue to drive forward cutting-edge research in catalytic environmental technologies.

Awards and Honors

Dr. Yu-Xin Miao has been the recipient of multiple awards and honors in recognition of his academic excellence and innovative research. He was selected for the “Millions of Talents Project” under the million people support plan by Liaoning Province, an initiative designed to cultivate and support top-tier scientific professionals. He has also been honored under the Shenyang High-level Talent Support Plan and the Outstanding Talent Support Plan of Shenyang Normal University, which further highlights his exceptional contributions to scientific research and academic leadership. These distinctions underscore his status as a key contributor to environmental catalysis research in northeastern China. In addition to these honors, Dr. Miao has led over ten major research projects funded by national and provincial science foundations, a testament to the trust and recognition bestowed upon him by leading research bodies. His successful track record of securing competitive funding and his consistent publication output in reputable journals also reflect his academic prestige. Furthermore, with three patents granted under his name, Dr. Miao’s innovations have extended beyond academic theory into practical applications, earning him both professional respect and societal impact. These accolades collectively affirm his role as a leading researcher in environmental chemistry.

Publications Top Notes

Title: Facile hydrothermal synthesis of hydroxyapatite nanosheets as highly “active” supports for stabilizing silver nanoparticles in toluene oxidation
Year: 2025

Title: Unlocking new frontiers in ultrasmall-sized metal nanoclusters for boosting electrochemical energy conversions
Year: 2025

Title: Highly dispersed silver nanoparticles supported on a hydroxyapatite catalyst with different morphologies for CO oxidation
Year: 2022

Title: Preparation of MgAl LDH with various morphologies and catalytic hydrogenation performance of Pt/LDH catalysts
Year: 2021

Conclusion

In conclusion, Dr. Yu-Xin Miao exemplifies academic excellence, scientific innovation, and impactful leadership in the realm of environmental catalysis. With a strong educational foundation and a Ph.D. from the State Key Laboratory of Fine Chemicals at Dalian University of Technology, he has cultivated a career dedicated to addressing critical environmental issues through advanced catalytic technologies. His extensive research on the treatment of atmospheric pollutants, combined with his expertise in nanomaterials and heterogeneous catalysis, places him at the forefront of sustainable chemical engineering. Dr. Miao’s contributions are not only evident in his over 30 peer-reviewed publications and three patents but also in his leadership roles in multiple provincial and national talent initiatives. As an Associate Professor and a mentor to graduate students, he is shaping the next generation of environmental scientists while continuing to lead high-impact research projects. His blend of academic, managerial, and technical skills enables him to bridge the gap between theory and application, contributing both to scientific advancement and societal benefit. Recognized through numerous awards and leadership positions, Dr. Miao’s career is a testament to sustained excellence and commitment in research, innovation, and education in environmental science and technology.

 

Likun Gao | Energy Sustainability | Best Researcher Award

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Prof. Dr. Likun Gao | Energy Sustainability | Best Researcher Award

Professor at Northeast forestry University, China

Professor Likun Gao is a pioneering researcher in the interdisciplinary field of advanced wood-based materials, serving at the School of Materials Science and Engineering, Northeast Forestry University, China. His work is at the forefront of integrating wood science with cutting-edge nanotechnology, particularly focusing on wood nanogenerators, electrocatalytic wood, and multifunctional self-healing materials. With a robust foundation in wood science and engineering, he has rapidly ascended as an influential academic voice in materials research. His innovations have practical implications for sustainable energy, water splitting, environmental sensing, and extreme-condition applications. Professor Gao has authored over 40 peer-reviewed publications in premier journals such as Chem. Soc. Rev., PNAS, Energy & Environmental Science, and Advanced Functional Materials. His contributions include several highly cited papers and journal covers, affirming the novelty and impact of his research. He also holds multiple patents and has co-authored important book chapters related to electrocatalysis and wood-based functional materials. Recognized through prestigious programs like China’s National Ten Thousand Talents and the CAST Young Elite Scientists Sponsorship, Gao exemplifies the next generation of scientific leadership in sustainable and intelligent materials. His commitment to interdisciplinary collaboration and scientific innovation positions him as a transformative figure in applied materials science.

Professional Profile

Education

Likun Gao’s educational journey reflects a deep and consistent focus on wood science and materials engineering, beginning with a Bachelor of Science in Wood Science and Engineering from Northeast Forestry University in 2014. Demonstrating early academic promise, he pursued his doctoral studies at the same institution, earning a Ph.D. in Wood Science and Technology in 2020. His doctoral research was marked by a growing interest in integrating biological materials with nanotechnology to produce functional composites. As part of his Ph.D. program, Gao was selected for an international research stint at the Georgia Institute of Technology, USA, from 2018 to 2020. There, he expanded his expertise in materials science and engineering, engaging with global experts and exploring the intersection of nanomaterials and bio-based resources. This international exposure enriched his methodological rigor and allowed him to contribute to several high-impact collaborations. His academic background forms the backbone of his innovative research portfolio and underpins his current leadership in multifunctional wood-based materials. The comprehensive, cross-continental training he received has equipped him with a unique perspective on the potential of sustainable materials in modern technology.

Professional Experience

Since March 2021, Professor Likun Gao has been serving as a full Professor at Northeast Forestry University’s School of Materials Science and Engineering. In this role, he leads a dynamic research group exploring the frontier of wood nanotechnology and sustainable energy materials. Building on his doctoral and international postdoctoral experiences, he has established an impressive track record of research output and innovation. Under his leadership, the lab has produced over 40 peer-reviewed journal articles, numerous high-impact papers, and several patents. His collaborations span interdisciplinary teams focused on energy conversion, smart materials, and environmental responsiveness. In addition to his scientific output, Professor Gao is also dedicated to mentoring students and early-career researchers. He regularly supervises graduate students, fostering an environment of creativity, innovation, and academic rigor. His teaching responsibilities include advanced courses in nanomaterials, wood science, and electrocatalysis. Beyond academic instruction, Gao actively contributes to national and international research projects and often serves as a reviewer for top-tier journals. His role as a professor is multifaceted—blending research, mentorship, collaboration, and academic service—which has rapidly elevated his stature in China’s scientific community and beyond.

Research Interest

Professor Likun Gao’s research interests lie at the convergence of sustainable materials science and advanced nanotechnology, focusing particularly on wood-derived functional materials. One of his core areas is the development of wood nanogenerators, including piezoelectric and triboelectric devices, as well as cellulose-based systems. These innovations provide new pathways for harvesting renewable energy from environmental sources, especially in flexible and wearable electronics. Another major focus is electrocatalytic wood, where Gao engineers wood-based single-atom electrocatalysts for applications like water splitting, targeting efficient and green hydrogen production. He also pioneers in multifunctional, self-healing wood-based materials that exhibit unique properties such as photothermal responsiveness, anti-icing, sensing, and environmental adaptability. These materials are particularly promising for use in extreme weather conditions and smart infrastructure. His research approach is distinctly bioinspired, aiming to replicate or enhance natural functionalities through molecular-level material engineering. By leveraging the structural anisotropy and hierarchical nature of wood, Gao is able to design novel platforms for catalysis and energy generation. His interests also span surface reconstruction mechanisms, dynamic active-site modulation, and intelligent material design, reflecting a deep commitment to creating smart, eco-friendly technologies.

Research Skills

Professor Gao possesses a robust and multifaceted skill set that bridges wood science, nanotechnology, materials engineering, and electrocatalysis. His expertise includes the fabrication and functionalization of wood-derived nanogenerators, capable of converting mechanical energy into electrical energy through triboelectric and piezoelectric effects. He is also skilled in the design and synthesis of single-atom electrocatalysts embedded in wood substrates, which are essential for enhancing the kinetics of water-splitting reactions. Gao’s technical toolkit includes advanced material characterization techniques such as SEM, TEM, XPS, Raman spectroscopy, and in situ operando methods, which he uses to explore catalytic mechanisms and interface dynamics. Additionally, he has substantial experience in surface modification strategies to imbue wood-based composites with photothermal, hydrophobic, and self-healing properties. His lab routinely integrates superhydrophobic coatings, carbonization techniques, and atomic doping to create responsive multifunctional materials. Professor Gao also has notable strengths in writing scientific publications, securing research grants, and patenting novel technologies. His collaborative work with international teams underscores his ability to work across disciplines and cultural contexts, making him an agile and resourceful scientist in the global research landscape.

Awards and Honors

Professor Likun Gao has garnered widespread recognition for his pioneering work in wood-based functional materials, receiving numerous prestigious awards that underscore his contributions to scientific innovation and academic excellence. In 2023, he was selected for China’s National Ten Thousand Talents Program for High-level Young Talents—one of the country’s highest honors for young researchers. A year prior, in 2022, he was awarded the Young Elite Scientists Sponsorship Program by the China Association for Science and Technology (CAST), an accolade reserved for researchers demonstrating extraordinary potential in advancing science and technology. He also received the Excellent Young Scholar Award from the Natural Science Foundation of Heilongjiang Province, recognizing his outstanding research in applied materials. Professor Gao has contributed to 3 book chapters and authored over 40 high-quality journal articles, several of which were highlighted as ESI Highly Cited Papers, journal cover stories, or Hot Papers. His intellectual property portfolio includes five patents, reflecting a commitment to practical innovation. These honors collectively affirm his leadership in the field and serve as milestones in a career defined by creativity, scientific rigor, and impactful problem-solving.

Conclusion

In summary, Professor Likun Gao stands as a dynamic and forward-thinking figure in the fields of materials science and wood-based nanotechnology. His research bridges the gap between nature and cutting-edge engineering, offering solutions for sustainable energy, smart materials, and functional composites. With a strong academic foundation, international exposure, and a commitment to interdisciplinary research, Gao has built a formidable reputation as a scientist, educator, and innovator. His work is not only scientifically profound but also socially and environmentally relevant, addressing global challenges like clean energy, climate resilience, and sustainable resource use. Through a combination of technical expertise, scholarly productivity, and leadership, Professor Gao has earned national and international recognition. As a young academic leader, he continues to push the boundaries of material innovation while fostering the next generation of researchers. With a track record of high-impact publications, prestigious awards, and cross-disciplinary collaboration, he is well-positioned to influence both academic advancements and industrial applications. The trajectory of his career reflects a deep-seated passion for discovery and a vision for materials that are both intelligent and sustainable.

Publications Top Notes

  1. Title: Wood-based triboelectric nanogenerator integrated with superhydrophobicity and photothermal-induced self-healing for high-temperature and high-humidity environment
    Authors: M. Wang, X. Li, D. Lv, P. He, C. Yang, J. Li, L. Gao*
    Year: 2025

  2. Title: High-Loading Single Atoms via Hierarchically Porous Nanospheres for Oxygen Reduction Reaction with Superior Activity and Durability
    Year: 2025

  3. Title: Self-supported N-doped carbon-coupled Ni–Co binary nanoparticle electrodes derived from bionic design of wood cell walls for durable overall water splitting
    Authors: C. Yang, R. Jin, Z. Liu, S. Li, D. Lv, J. Liu, J. Li, Z. Lin*, L. Gao*
    Journal: Journal of Materials Chemistry A
    Year: 2024

  4. Title: Collaborative integration of ultrafine Fe₂P nanocrystals into Fe, N, P-codoped carbon nanoshells for highly-efficient oxygen reduction
    Year: 2023
    Citations: 56