Zhigang Chen | Chemistry | Best Researcher Award

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Dr. Zhigang Chen | Chemistry | Best Researcher Award

Associate Professor from Chongqing University of Technology, China

Zhigang Chen is an accomplished researcher and Associate Professor at the School of Energy Catalysis, Chongqing University of Technology. With a strong academic background in physical chemistry and materials science, he has developed a research niche in single-atom catalysis and advanced in situ characterization techniques. Dr. Chen has demonstrated an exceptional ability to combine theoretical knowledge with experimental innovation, resulting in significant contributions to the field of heterogeneous catalysis. His research has been widely recognized and published in prestigious journals such as Nature Communications, PNAS, Nano Letters, ACS Catalysis, and Small, with many works authored as the first or corresponding author. Throughout his academic and professional career, Dr. Chen has emphasized the development of scalable, high-performance catalysts for electrochemical applications, addressing key challenges in sustainable energy. His work not only advances fundamental understanding of catalyst behavior but also offers practical implications for energy conversion and storage technologies. Driven by scientific curiosity and a strong commitment to impactful research, Dr. Chen continues to explore novel materials and techniques with a vision to revolutionize the field of catalysis through innovation, precision, and interdisciplinary collaboration.

Professional Profile

Education

Zhigang Chen holds a robust academic foundation in materials science and physical chemistry, having completed his education at some of China’s most prestigious institutions. He earned his Bachelor’s degree in Materials Science and Engineering from Chongqing University of Technology in 2014, laying the groundwork for his future specialization in catalysis and nanotechnology. He then pursued a Master’s degree in Physical Chemistry at the School of Sciences, Shanghai University, from 2014 to 2017. During this time, he honed his skills in chemical analysis, reaction mechanisms, and materials characterization, which became pivotal in his later research. For his doctoral studies, Dr. Chen attended the University of Science and Technology of China, one of the country’s leading research universities, where he earned his Ph.D. in Physical Chemistry in 2020. His doctoral work delved into the mechanisms and design of advanced catalytic systems, particularly at the nanoscale level. Following his Ph.D., he undertook a postdoctoral fellowship at the Suzhou Institute of Nano-Tech and Nano-Bionics, Chinese Academy of Sciences, specializing in surface catalysis. This rich academic trajectory has equipped him with a comprehensive understanding of both the theoretical and practical aspects of catalysis and advanced materials science.

Professional Experience

Zhigang Chen began his professional journey with a strong academic orientation, culminating in his current role as an Associate Professor at the School of Energy Catalysis, Chongqing University of Technology, where he has been serving since March 2023. Prior to this, he completed a postdoctoral fellowship at the Suzhou Institute of Nano-Tech and Nano-Bionics, Chinese Academy of Sciences, from 2020 to 2023. There, he focused on surface catalysis and further deepened his expertise in nanostructured materials and their electrochemical applications. His postdoctoral research also emphasized in situ spectroscopic techniques, which enabled a more profound understanding of catalyst behavior under real-time operational conditions. Dr. Chen’s academic appointments reflect a continuous trajectory of growth, supported by both fundamental scientific training and advanced experimental research. Throughout his professional career, he has maintained a strong publishing record in internationally renowned journals and has taken on increasing responsibilities as a lead and corresponding author. His current role includes supervising graduate students, developing cutting-edge research projects in energy catalysis, and contributing to the scientific community through collaborations and peer-reviewed publications. His professional pathway showcases both academic depth and research leadership in a rapidly evolving scientific field.

Research Interests

Zhigang Chen’s research interests lie at the intersection of material science, surface chemistry, and energy technology, with a primary focus on the development and scale-up of single-atom catalysts. These advanced materials offer high catalytic efficiency, selectivity, and stability—key parameters for energy-related applications such as hydrogen evolution, oxygen evolution, and carbon dioxide reduction. His work is grounded in physical chemistry and is highly interdisciplinary, integrating concepts from solid-state chemistry, surface science, and electrochemical engineering. Dr. Chen is particularly interested in the application of in situ spectroscopic techniques such as Raman spectroscopy, X-ray photoelectron spectroscopy (XPS), and X-ray absorption spectroscopy (XAS), which allow real-time investigation of catalytic behavior under operational conditions. His overarching research goal is to develop highly active and durable catalytic systems that contribute to sustainable and clean energy solutions. The combination of scalable material synthesis and in-depth mechanistic studies places his research at the frontier of nanocatalysis and materials innovation. Furthermore, he seeks to expand his work into industrially viable catalytic systems that can be deployed in real-world applications, thereby bridging the gap between fundamental research and applied technology.

Research Skills

Zhigang Chen possesses a diverse and advanced set of research skills that distinguish him in the field of catalysis and materials science. He is highly proficient in the synthesis and scale-up of single-atom catalysts, which involves complex procedures of atomic dispersion, substrate preparation, and post-treatment to achieve high catalytic performance. His work also extensively utilizes advanced characterization methods, particularly in situ spectroscopic techniques such as Raman spectroscopy, XPS (X-ray photoelectron spectroscopy), and XAS (X-ray absorption spectroscopy). These techniques enable him to monitor and analyze chemical reactions and structural changes of catalysts in real-time under operating conditions, providing critical insights into reaction mechanisms and material behavior. In addition to experimental techniques, Dr. Chen demonstrates strong skills in data interpretation, scientific writing, and critical review, as reflected in his numerous first-author publications in high-impact journals. His background in physical chemistry further enhances his ability to understand reaction kinetics, thermodynamics, and surface interactions at the atomic level. Moreover, he is adept at collaborating across disciplines, integrating materials science with electrochemistry and nanotechnology, which allows him to approach problems from multiple scientific perspectives. These research competencies position him as a leading innovator in catalyst development.

Awards and Honors

Zhigang Chen’s scholarly contributions have earned him recognition within the scientific community, as evidenced by his publication record in premier journals such as Nature Communications, PNAS, Nano Letters, Nano Energy, and ACS Catalysis. While specific awards or honors are not listed in his current profile, his recurring presence as the first or corresponding author in these top-tier journals is itself a mark of distinction. His research achievements reflect not only academic excellence but also innovation and leadership in the competitive field of catalysis and nanomaterials. Publishing in journals of this caliber requires stringent peer review and high-impact findings, indicating that Dr. Chen’s work consistently meets international standards of research excellence. Furthermore, his appointment as Associate Professor at a relatively early stage in his career signifies institutional recognition of his potential and expertise. He is also trusted with mentorship roles and leads significant research initiatives within his department. As his career progresses, it is expected that Dr. Chen will continue to receive formal awards and honors for his pioneering research, interdisciplinary collaborations, and contributions to advancing energy technologies.

Conclusion

Zhigang Chen stands out as a dynamic and innovative researcher whose work in single-atom catalysis and in situ spectroscopy has made a notable impact on the field of energy catalysis. His academic training, postdoctoral specialization, and current faculty role all reflect a focused and evolving career dedicated to advancing sustainable technologies through materials innovation. With a solid foundation in physical chemistry and materials science, Dr. Chen has developed advanced skills in catalyst synthesis and real-time analytical techniques, positioning him at the forefront of modern catalysis research. His extensive publication record in prestigious journals underscores his ability to produce high-quality, impactful research. Moreover, his current research aligns with global priorities such as clean energy and environmental sustainability, making his contributions both timely and socially relevant. As an emerging leader in his field, Dr. Chen has the potential to influence both academic research and industrial practices. With continued focus on interdisciplinary collaboration and application-driven research, he is well-poised to achieve greater scientific milestones. Overall, his profile makes him a strong contender for awards that recognize innovative and high-impact research.

 

 

Zhishuai Geng | Chemistry | Best Researcher Award

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Prof. Zhishuai Geng | Chemistry | Best Researcher Award

Assistant Professor from Beijing Institute of Technology, China

Zhishuai Geng is a highly accomplished researcher and Assistant Professor at the School of Materials Science and Engineering, Beijing Institute of Technology. With a strong academic background and a distinguished postdoctoral tenure at the University of California, Santa Barbara, Dr. Geng has positioned himself at the forefront of polymer materials research. His work encompasses dynamic polymer networks, self-healing materials, recyclable polymers, and flame-retardant systems, all aimed at creating sustainable, multifunctional, and high-performance materials. He has authored and co-authored numerous publications in top-tier journals such as ACS Applied Materials & Interfaces, Macromolecules, Chemical Engineering Journal, and Journal of Polymer Science. In addition to his academic contributions, Dr. Geng is also an inventor with several patents in the areas of antibacterial polyurethanes and functional polymeric materials. His engagement with the scientific community is evident through his active peer-review duties for prominent journals and participation in major scientific conferences. Dr. Geng’s innovative work reflects a balance between fundamental chemistry and real-world applications, earning him recognition as an emerging leader in the field. His commitment to solving complex challenges in materials science through interdisciplinary strategies makes him an excellent candidate for prestigious research awards and future academic leadership roles.

Professional Profile

Education

Zhishuai Geng’s academic journey began with a Bachelor of Science in Materials Chemistry from Nankai University, China, completed in 2012. This foundational education grounded him in chemical principles essential for advanced materials research. He then pursued his Ph.D. at the Georgia Institute of Technology in the School of Chemistry and Biochemistry, where he conducted innovative research from 2012 to 2018. His doctoral work focused on polymer chemistry and functional macromolecular systems, laying the groundwork for his future scientific pursuits. Following this, Dr. Geng expanded his expertise internationally through a postdoctoral fellowship at the University of California, Santa Barbara, from 2018 to 2021. There, he worked in the Materials Research Laboratory, a globally recognized hub for cutting-edge research in polymer science and materials engineering. This postdoctoral experience significantly enriched his knowledge in covalent adaptable networks, click chemistry, and flame-retardant materials. In May 2021, he began his role as an Assistant Professor at the Beijing Institute of Technology, where he continues to push the boundaries of polymer innovation. His diverse educational background, spanning elite institutions in both China and the United States, equips him with a global perspective and the technical versatility necessary for leading impactful research in materials science.

Professional Experience

Zhishuai Geng’s professional experience reflects a dynamic and progressive trajectory in academia and research. His career began with an intensive postdoctoral research appointment at the University of California, Santa Barbara, between July 2018 and April 2021. There, he collaborated with leading materials scientists on high-impact research projects, gaining deep expertise in covalent adaptable networks, polymer synthesis, and functional material systems. This period also fostered his proficiency in publishing within high-ranking journals and filing patent applications. In May 2021, Dr. Geng transitioned into a faculty role as an Assistant Professor in the School of Materials Science and Engineering at Beijing Institute of Technology. In this position, he leads a research group focused on the design and development of advanced polymeric materials, addressing key challenges in recyclability, mechanical performance, and multifunctionality. In addition to research, he actively mentors students and contributes to academic service through reviewing scholarly articles and participating in academic societies. His professional affiliations include roles in the Georgia Tech Polymer Network and the Center for the Science and Technology of Advanced Materials and Interfaces. Through these diverse experiences, Dr. Geng has established himself as a capable leader and innovator in the field of materials science and engineering.

Research Interest

Dr. Zhishuai Geng’s research interests lie at the intersection of polymer chemistry, materials engineering, and sustainable design. His primary focus is on dynamic polymer networks and covalent adaptable networks, often known as vitrimers, which allow for reprocessing, self-healing, and enhanced material lifespans. He is particularly interested in developing self-healing polymers that combine structural performance with autonomous repair capabilities. Another major area of his work involves flame-retardant polymer materials, where he has contributed significantly to the design of macromolecular and reactive flame retardants, especially phosphorus-based systems. These materials aim to enhance fire safety in polymers without compromising mechanical properties. Dr. Geng is also engaged in creating antimicrobial materials for biomedical applications, an area that addresses critical needs in healthcare and public safety. Furthermore, he explores surface modification techniques using covalent bonding strategies to enhance compatibility and functionality in complex systems. His interdisciplinary interests integrate organic chemistry, polymer physics, and nanotechnology, enabling the design of advanced materials with multiple, often synergistic, functions. Dr. Geng’s work not only contributes to academic knowledge but also holds strong translational potential for applications in electronics, healthcare, and environmental sustainability.

Research Skills

Zhishuai Geng has cultivated a comprehensive skill set that spans the synthesis, characterization, and application of advanced polymeric materials. His expertise in dynamic polymer networks and covalent adaptable networks has enabled him to design materials with properties such as self-healing, recyclability, and thermal responsiveness. He is proficient in advanced polymer synthesis techniques, including click chemistry, post-polymerization modification, and coordination crosslinking. These methods are used to construct multifunctional systems with tailored mechanical and thermal properties. Dr. Geng is also skilled in developing flame-retardant materials through phosphorus-based and macromolecular strategies, demonstrating an ability to balance fire resistance with mechanical integrity. His work in antimicrobial polymer design reflects his capacity for integrating biofunctional components into synthetic frameworks. Technically, he is adept at using a wide range of analytical tools, including spectroscopy (FTIR, NMR), thermal analysis (TGA, DSC), and mechanical testing. His experience also extends to surface engineering, nanoporous structure fabrication, and dielectric property testing. Additionally, Dr. Geng’s role as an active peer reviewer for journals like Macromolecules, Chemical Engineering Journal, and Biomacromolecules demonstrates his analytical rigor and recognition in the field. These research skills collectively enable him to tackle complex scientific challenges and lead high-impact projects across academia and industry.

Awards and Honors

While specific awards are not explicitly listed, Zhishuai Geng’s achievements in research and innovation reflect significant professional recognition. His selection as a postdoctoral fellow at the prestigious University of California, Santa Barbara, highlights his early potential and research promise. Moreover, his current appointment as an Assistant Professor at Beijing Institute of Technology—a top-tier university in China—demonstrates institutional trust in his expertise and leadership. Dr. Geng has filed and received multiple patents, including a Chinese patent for antibacterial polyurethane (CN 116041660 A) and a U.S. patent for polycation synthesis (US 11,589,590 B2), underscoring the novelty and applicability of his research. He has published in leading journals across the fields of chemistry and materials science and has participated in international conferences, such as the American Chemical Society (ACS) National Meeting. Additionally, his role as a frequent peer reviewer for highly regarded journals is an implicit recognition of his scholarly authority. His involvement in scientific organizations like the Georgia Tech Polymer Network and the Center for Advanced Materials and Interfaces further affirms his standing in the research community. With continued excellence, formal awards and honors are likely to follow in his advancing academic career.

Conclusion

Zhishuai Geng exemplifies the qualities of a dedicated, innovative, and impactful researcher in the field of materials science and polymer chemistry. His work demonstrates a deep commitment to solving pressing global challenges through the development of recyclable, flame-retardant, self-healing, and antimicrobial polymer materials. With a solid academic background, including training at Georgia Institute of Technology and postdoctoral research at UC Santa Barbara, Dr. Geng brings a global perspective and technical sophistication to his role as Assistant Professor at Beijing Institute of Technology. His prolific publication record, collaborative patent activity, and active involvement in peer reviewing indicate both scientific credibility and community engagement. While his professional recognition could be further elevated through formal academic awards and expanded research leadership, his contributions already mark him as a rising leader in his domain. Dr. Geng’s ability to bridge fundamental research and real-world application positions him as a valuable asset to the academic and industrial research ecosystems. He is an ideal candidate for research honors such as the Best Researcher Award, and with continued achievements, he is poised to influence the future of sustainable and multifunctional material development on a global scale.

Publication Top Notes

1. Ultrarobust, Self-Healing Poly(urethane-urea) Elastomer with Superior Tensile Strength and Intrinsic Flame Retardancy Enabled by Coordination Cross-Linking
Authors: Yuxin Luo, Meiyan Tan, Jaeman Shin, Cheng Zhang, Shiyuan Yang, Ningning Song, Wenchao Zhang, Yunhong Jiao, Jixing Xie, Zhishuai Geng, et al.
Journal: ACS Applied Materials & Interfaces
Year: 2024
DOI: 10.1021/acsami.4c08185

2. Metformin-Mediated Fast Charge-Reversal Nanohybrid for Deep Penetration Piezocatalysis-Augmented Chemodynamic Immunotherapy of Cancer
Authors: Yuan Wang, Qingshuang Tang, Ruiqi Wu, Shiyuan Yang, Zhishuai Geng, Ping He, Xiaoda Li, Qingfeng Chen, Xiaolong Liang
Journal: ACS Nano
Year: 2024
DOI: 10.1021/acsnano.3c11174
Citations: 3

3. Dual Nucleation Sites Induced by ZIF-67 Towards Mismatch of Polyphosphazene Hollow Sub-Micron Polyhedrons and Nanospheres in Flame Retardant Epoxy Matrix
Authors: Xiaoning Song, Boyou Hou, Zhengde Han, Ye-Tang Pan, Zhishuai Geng, Laia Haurie Ibarra, Rongjie Yang
Journal: Chemical Engineering Journal
Year: 2023
DOI: 10.1016/j.cej.2023.144278

4. Neighboring Group Participation in Ionic Covalent Adaptable Networks
Authors: Lindsay L. Robinson, Eden S. Taddese, Jeffrey L. Self, Christopher M. Bates, Javier Read de Alaniz, Zhishuai Geng, Craig J. Hawker
Journal: Macromolecules
Year: 2022
DOI: 10.1021/acs.macromol.2c01618
Citations: 4

5. Gold(I)-Catalyzed Tandem Cyclization/Hydroarylation of o-Alkynylphenols with Haloalkynes
Authors: Jiawen Wu, Cunbo Wei, Fen Zhao, Wenqian Du, Zhishuai Geng, Zhonghua Xia
Journal: The Journal of Organic Chemistry
Year: 2022
DOI: 10.1021/acs.joc.2c01804
Citations: 5

6. Multielement Flame-Retardant System Constructed with Metal POSS–Organic Frameworks for Epoxy Resin
Authors: Boyou Hou, Wenyuan Zhang, Hongyu Lu, Kunpeng Song, Zhishuai Geng, Xinming Ye, Ye-Tang Pan, Wenchao Zhang, Rongjie Yang
Journal: ACS Applied Materials & Interfaces
Year: 2022
DOI: 10.1021/acsami.2c14740

7. Azide-Substituted Polylactide: A Biodegradable Substrate for Antimicrobial Materials via Click Chemistry Attachment of Quaternary Ammonium Groups
Authors: Pranav P. Kalelkar, Zhishuai Geng, M.G. Finn, David M. Collard
Journal: Biomacromolecules
Year: 2019
DOI: 10.1021/acs.biomac.9b00504
Citations: 19

8. Placing Functionality Where You Want: The Allure of Sequence Control
Authors: Zhishuai Geng, J. Lee, Craig J. Hawker
Journal: Chem
Year: 2019
DOI: 10.1016/j.chempr.2019.09.007

9. A Hierarchically Nanostructured Cellulose Fiber-Based Triboelectric Nanogenerator for Self-Powered Healthcare Products
Authors: X. He, H. Zou, Z. Geng, X. Wang, W. Ding, F. Hu, Y. Zi, C. Xu, S.L. Zhang, H. Yu, et al.
Journal: Advanced Functional Materials
Year: 2018
DOI: 10.1002/adfm.201805540

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

 

 

 

Hyunseob Lim | Chemistry | Best Researcher Award

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Prof. Hyunseob Lim | Chemistry | Best Researcher Award

Associate Professor From Gwangju Institute of Science and Technology, South Korea

Dr. Hyunseob Lim is a distinguished scientist and academic whose research career spans over a decade with a strong emphasis on chemistry, nanomaterials, and two-dimensional (2D) materials. He currently holds multiple appointments, including Associate Professor in the Department of Chemistry at Gwangju Institute of Science and Technology (GIST), Research Fellow at the Institute for Basic Science (IBS), and Adjunct Professor in Semiconductor Engineering at GIST. Dr. Lim’s work bridges the gap between fundamental science and real-world applications, with contributions to material synthesis, surface chemistry, quantum materials, and optoelectronic devices. He has consistently demonstrated leadership in pioneering methods for material characterization and epitaxial growth, reflected in his extensive publication record in high-impact journals. His multidisciplinary approach integrates experimental innovation with theoretical insight, making him a key contributor to the advancement of nano- and quantum technologies in Korea and beyond. Throughout his career, Dr. Lim has earned a reputation for academic rigor, collaborative spirit, and visionary research leadership. His professional journey reflects a dynamic progression from early postdoctoral roles in Korea and Japan to securing tenure-track and professorial positions at leading research institutions. Dr. Lim continues to expand the frontiers of material science through innovative research, mentoring, and interdisciplinary collaboration.

Professional Profile

 Education

Dr. Hyunseob Lim completed both his undergraduate and doctoral studies at the prestigious Pohang University of Science and Technology (POSTECH) in South Korea, a leading institution renowned for its strong emphasis on research and innovation in science and engineering. He earned his Bachelor of Science (B.S.) degree in Chemistry in February 2006, establishing a solid foundation in the core principles of chemical sciences. Driven by a deep interest in materials chemistry and nanotechnology, Dr. Lim continued his academic journey at POSTECH, where he pursued a Ph.D. in Chemistry under the guidance of Professor HeeCheul Choi. During his doctoral research from March 2006 to February 2011, he focused on the functional surface chemistry of carbon-based nanomaterials, including fullerenes, carbon nanotubes, and graphene. His dissertation, titled “The Studies of Functional Surface Chemistry on Fullerene, Carbon Nanotube and Graphene: Development, Characterization and Application,” reflects his early and profound engagement with nanostructured materials, a theme that would continue throughout his career. His doctoral work demonstrated not only technical expertise in synthesis and surface characterization but also a visionary outlook on the application potential of low-dimensional carbon systems. This solid academic foundation laid the groundwork for his later success in cutting-edge research on 2D materials and hybrid nanostructures.

Professional Experience

Dr. Hyunseob Lim has built a distinguished academic and research career marked by progressive appointments at leading institutions in Korea and Japan. Since 2022, he has served as an Associate Professor in the Department of Chemistry at the Gwangju Institute of Science and Technology (GIST), where he is also a Research Fellow at the Center for Quantum Conversion Research at the Institute for Basic Science (IBS) from 2024 and an Adjunct Professor in the Department of Semiconductor Engineering at GIST starting in 2025. Prior to this, he was an Assistant Professor at GIST (2019–2022) and at Chonnam National University (2017–2019), contributing significantly to teaching and research development in both institutions. His earlier career includes a tenure-track Research Fellowship at the IBS Center for Multidimensional Carbon Materials (2014–2017) and an Adjunct Professorship at UNIST (2014–2016). Dr. Lim’s international experience includes postdoctoral research at RIKEN in Japan (2012–2014) and a visiting scientist role at RIKEN’s BYON Initiative (2011–2012). He also worked as a postdoctoral researcher at POSTECH’s Center for Electron-Phonon Behavior (2011–2012). This diverse trajectory has allowed Dr. Lim to cultivate deep expertise in advanced materials research, interdisciplinary collaboration, and high-impact publication, reinforcing his status as a respected leader in the field of nanoscience.

Research Interest

Dr. Hyunseob Lim’s research is centered at the intersection of surface chemistry, low-dimensional materials, and advanced nanostructures, with a strong focus on two-dimensional (2D) materials such as graphene, MoS₂, and covalent organic frameworks. His scientific curiosity lies in understanding the fundamental chemistry that governs the growth, transformation, and interaction of these materials at the atomic scale. He is particularly interested in exploring how surface functionalization and interface engineering can modulate electronic, optical, and catalytic properties in 2D systems. His research spans both experimental and theoretical approaches to uncover mechanisms of epitaxial growth, phase transition, and defect engineering in nanomaterials. Dr. Lim also investigates hybrid nanostructures that combine inorganic and organic components to achieve synergistic functionality for next-generation applications, including flexible electronics, quantum devices, energy storage systems, and neuromorphic computing. He is deeply engaged in developing residue-free and scalable synthesis techniques, as well as novel photochemical and electrochemical strategies for device-level integration. Furthermore, his interest extends to in situ and operando characterization, enabling real-time observation of material behavior under working conditions. Through these multidisciplinary endeavors, Dr. Lim aims to bridge the gap between fundamental materials science and practical device applications, contributing to the advancement of both academic knowledge and technological innovation.

Research Skills

Dr. Hyunseob Lim possesses a broad and versatile skill set that spans the synthesis, characterization, and functionalization of advanced nanomaterials, with a core emphasis on two-dimensional materials and surface chemistry. He is highly proficient in chemical vapor deposition (CVD) and solution-based synthesis techniques for producing atomically thin materials such as graphene, MoS₂, and various covalent organic frameworks. His expertise includes precise control of molecular precursors and substrate interactions to engineer material growth modes and morphologies. Dr. Lim is adept in in situ and ex situ characterization methods, including Raman spectroscopy, scanning tunneling microscopy (STM), atomic force microscopy (AFM), X-ray photoelectron spectroscopy (XPS), and transmission electron microscopy (TEM), allowing detailed surface and interface analysis at the nanoscale. He also has experience in spectroelectrochemical and photophysical studies to explore catalytic, optoelectronic, and energy-related properties of nanostructures. In addition, he integrates computational approaches and theoretical modeling to understand material behavior and guide experimental design. His ability to translate fundamental findings into real-world applications is evident in his development of residue-free transfer methods, high-performance device architectures, and responsive materials for sensing, energy storage, and synaptic electronics. These interdisciplinary capabilities have positioned Dr. Lim as a dynamic researcher bridging chemistry, materials science, and applied nanotechnology.

Awards and Honors

Throughout his career, Dr. Hyunseob Lim has been recognized for his outstanding contributions to the fields of surface chemistry, nanomaterials, and two-dimensional materials research. His pioneering work in the synthesis and characterization of low-dimensional materials has garnered attention in both national and international scientific communities. He has received numerous accolades for his high-impact publications in prestigious journals such as Nature Communications, Advanced Materials, Nano Letters, and ACS Nano, reflecting the academic value and innovation of his research. During his postdoctoral training and early faculty appointments, he was awarded competitive research fellowships and grant funding from renowned institutions, including the Institute for Basic Science (IBS) in Korea and RIKEN in Japan, where he conducted breakthrough research on carbon-based nanomaterials. His interdisciplinary collaborations have led to influential patents and technology transfers in the fields of advanced materials and optoelectronics. In recognition of his contributions to education and mentoring, he has been honored by student bodies and academic committees at both GIST and Chonnam National University. His dedication to excellence and continuous advancement in scientific knowledge underscores his reputation as a leading figure in materials chemistry. These honors reflect not only his academic impact but also his commitment to fostering a culture of innovation and integrity in science.

Conclusion

Dr. Hyunseob Lim stands as a distinguished scholar and innovator in the realm of chemistry and materials science, with a career that exemplifies academic excellence, research creativity, and interdisciplinary collaboration. From his foundational training at POSTECH to his leadership roles at GIST and the Institute for Basic Science, Dr. Lim has consistently pushed the frontiers of nanomaterials, surface chemistry, and two-dimensional systems. His deep understanding of synthesis, surface analysis, and device integration has enabled the development of cutting-edge technologies, contributing significantly to both fundamental science and real-world applications. Through an impressive body of scholarly work, Dr. Lim has not only advanced the scientific understanding of material behaviors at the atomic level but has also laid the groundwork for innovations in electronics, energy storage, and sensing platforms. As an educator, he continues to inspire the next generation of scientists, fostering a research environment that values curiosity, rigor, and ethical inquiry. His ongoing commitment to collaborative research, both nationally and internationally, positions him as a key player in the global scientific community. Looking forward, Dr. Lim is poised to continue making transformative contributions to materials science, chemistry, and nanotechnology, driving innovation across academia and industry.

Publications Top Notes

  1. Title: Exploring the efficient catalytic activity of mixed-phase palladium selenides in oxygen reduction reaction
    Authors: Hyeonju Kim, Sua Yu, Sunghyun Kim, Hafidatul Wahidah, Jong-Guk Ahn, Chaehyeon Ahn, Soyoung Kim, Jong Wook Hong, Sukwon Hong, Hyunseob Lim
    Year: 2025

  2. Title: Au@h‐BN Core–Shell Nanostructure as Advanced Shell‐Isolated Nanoparticles for In Situ Electrochemical Raman Spectroscopy in Alkaline Environments
    Authors: Jee Hyeon Kim, Jihyun Ra, Younghee Park, Junyeon Yoon, Eunji Lee, Hyunseob Lim
    Year: 2025

  3. Title: Residue‐Free Fabrication of 2D Materials Using van der Waals Interactions
    Authors: Minyoung Lee, Changho Kim, Soon‐Yong Kwon, Kayoung Lee, Giyoon Kwak, Hyunseob Lim, Jae Hun Seol
    Year: 2025

  4. Title: Proton-electron coupling and mixed conductivity in a hydrogen-bonded coordination polymer
    Authors: Minju Park, Huiyeong Ju, Joohee Oh, Kwangmin Park, Hyunseob Lim, Seok Min Yoon, Intek Song
    Year: 2025

  5. Title: Photochemical and Patternable Synthesis of 2D Covalent Organic Framework Thin Film Using Dynamic Liquid/Solid Interface
    Authors: Taewoong Kim, Joohee Oh, Seung Cheol Kim, Jong‐Guk Ahn, Soyoung Kim, Young Yong Kim, Hyunseob Lim
    Year: 2024

  6. Title: The effect of photodissociation of confined water on photoemission behaviors of monolayer MoS2
    Authors: Chaehyeon Ahn, Jong-Guk Ahn, Seokmo Hong, Hyun Woo Kim, Hyunseob Lim
    Year: 2024

  7. Title: Anomalous one-dimensional quantum confinement effect in graphene nanowrinkle
    Authors: Jong-Guk Ahn, Jee Hyeon Kim, Minhui Lee, Yousoo Kim, Jaehoon Jung, Hyunseob Lim
    Year: 2023

  8. Title: Engineering Geometric Electrodes for Electric Field‐Enhanced High‐Performance Flexible In‐Plane Micro‐Supercapacitors
    Authors: Jihong Kim, Sung Min Wi, Jong‐Guk Ahn, Sangjun Son, HeeYoung Lim, Yeonsu Park, Hye Ji Eun, Jong Bae Park, Hyunseob Lim, Sangyeon Pak et al.
    Year: 2023

  9. Title: Critical Role of Surface Termination of Sapphire Substrates in Crystallographic Epitaxial Growth of MoS₂ Using Inorganic Molecular Precursors
    Authors: Younghee Park, Chaehyeon Ahn, Jong-Guk Ahn, Jee Hyeon Kim, Jaehoon Jung, Juseung Oh, Sunmin Ryu, Soyoung Kim, Seung Cheol Kim, Taewoong Kim et al.
    Year: 2023

  10. Title: Synthesis of monolayer 2D MoS₂ quantum dots and nanomesh films by inorganic molecular chemical vapor deposition for quantum confinement effect control
    Authors: Chaehyeon Ahn, Hyunseob Lim
    Year: 2022

  11. Title: Van Hove Singularity in Graphene Nanowrinkle Grown on Ni(111) Generated by Pseudo One-Dimensional Electron Confinement
    Authors: Jong-Guk Ahn, Jee Hyeon Kim, Minhui Lee, Yousoo Kim, Jaehoon Jung, Hyunseob Lim
    Year: 2022

  12. Title: Vapor pressure-controllable molecular inorganic precursors for growth of monolayer WS₂: Influence of precursor-substrate interaction on growth thermodynamics
    Authors: Jee Hyeon Kim, Chaehyeon Ahn, Jong-Guk Ahn, Younghee Park, Soyoung Kim, Daehyun Kim, Jaeyoon Baik, Jaehoon Jung, Hyunseob Lim
    Year: 2022

  13. Title: Sustainable Surface-Enhanced Raman Substrate with Hexagonal Boron Nitride Dielectric Spacer for Preventing Electric Field Cancellation at Au–Au Nanogap
    Authors: Jong-Guk Ahn, Gyeonghun Yeo, Yeji Han, Younghee Park, Jong Wook Hong, Hyunseob Lim
    Year: 2021

  14. Title: Controlled Photoinduced Electron Transfer from InP/ZnS Quantum Dots through Cu Doping: A New Prototype for the Visible-Light Photocatalytic Hydrogen Evolution Reaction
    Authors: Jiwon Bang, Sankar Das, Eun-Jin Yu, Kangwook Kim, Hyunseob Lim, Sungjee Kim, Jong Wook Hong
    Year: 2020

  15. Title: Centimeter-Scale and Highly Crystalline Two-Dimensional Alcohol: Evidence for Graphenol (C₆OH)
    Authors: Hyunseob Lim, Younghee Park, Minhui Lee, Jong-Guk Ahn, Bao Wen Li, Da Luo, Jaehoon Jung, Rodney S. Ruoff, Yousoo Kim
    Year: 2020

  16. Title: Highly Oriented Monolayer Graphene Grown on a Cu/Ni(111) Alloy Foil
    Authors: Huang, M., Biswal, M., Park, H.J., Jin, S., Qu, D., Hong, S., Zhu, Z., Qiu, L., Luo, D., Liu, X., et al.
    Year: 2018

  17. Title: Synthesis of a Scalable Two-Dimensional Covalent Organic Framework (COF) by Photon-assisted Imine Condensation Reaction on the Water Surface
    Authors: Kim, S., Lim, H., Lee, J., Choi, H.C.
    Year: 2018

  18. Title: Controlled Folding of Single Crystal Graphene
    Authors: Wang, B., Huang, M., Kim, N.Y., Cunning, B.V., Huang, Y., Qu, D., Chen, X., Jin, S., Biswal, M., Zhang, X., et al.
    Year: 2017

  19. Title: Conversion of Langmuir-Blodgett monolayers and bilayers of poly(amic acid) through polyimide to graphene
    Authors: Jo, H.J., Lyu, J.H., Ruoff, R.S., Lim, H., Yoon, S.I., Jeong, H.Y., Shin, T.J., Bielawski, C.W., Shin, H.S.
    Year: 2017

  20. Title: Probing Evolution of Twist-Angle-Dependent Interlayer Excitons in MoSe₂/WSe₂ van der Waals Heterostructures
    Authors: Nayak, P.K., Horbatenko, Y., Ahn, S., Kim, G., Lee, J.-U., Ma, K.Y., Jang, A.-R., Lim, H., Kim, D., Ryu, S., et al.
    Year: 2017

  21. Title: Rapid Photochemical Synthesis of Sea-Urchin-Shaped Hierarchical Porous COF-5 and Its Lithography-Free Patterned Growth
    Authors: Kim, S., Park, C., Lee, M., Song, I., Kim, J., Lee, M., Jung, J., Kim, Y., Lim, H., Choi, H.C.
    Year: 2017

Shaotao BAI | Chemistry | Best Researcher Award

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Prof. Shaotao BAI | Chemistry | Best Researcher Award

Professor from Shenzhen Polytechnic University, China

Professor Shaotao Bai is a distinguished academic and researcher specializing in sustainable catalysis and engineering. He currently serves as a Principal Investigator, Assistant Dean, and Director of the Center for Carbon-Neutrality Catalysis and Engineering at Shenzhen Polytechnic University. His work focuses on applied homogeneous and heterogeneous catalysis, computational catalysis, and the development of innovative solutions for CO₂ capture and utilization. With a robust background in both theoretical and practical aspects of catalysis, Professor Bai has made significant contributions to advancing carbon-neutral technologies. His research has been widely recognized and has had a substantial impact on the field of sustainable energy.

Professional Profile

Education

Professor Bai’s academic journey laid a solid foundation for his career in catalysis and sustainable engineering. He earned his doctoral degree in a field pertinent to his current research focus, equipping him with the necessary knowledge and skills to excel in both academic and professional settings. His education emphasized the principles of chemical engineering and catalysis, providing him with a comprehensive understanding of the mechanisms and applications of catalytic processes. This strong educational background has been instrumental in his ability to lead cutting-edge research projects and contribute meaningfully to the scientific community.

Professional Experience

In his current role at Shenzhen Polytechnic University, Professor Bai holds multiple leadership positions, including Principal Investigator, Assistant Dean, and Director of the Center for Carbon-Neutrality Catalysis and Engineering. These roles involve overseeing research initiatives, managing academic programs, and leading efforts to develop sustainable catalytic processes. Prior to this, he gained valuable experience in various academic and research institutions, where he honed his expertise in applied catalysis and computational methods. His professional journey reflects a consistent commitment to advancing the field of catalysis and addressing global challenges related to carbon emissions and energy sustainability.

Research Interests

Professor Bai’s research interests are centered around sustainable catalysis and engineering, with a particular focus on carbon-neutral technologies. He is deeply engaged in the development of both homogeneous and heterogeneous catalytic systems aimed at efficient CO₂ capture and utilization. Additionally, his work encompasses computational catalysis, where he employs theoretical models to predict and optimize catalytic behaviors. By integrating experimental and computational approaches, Professor Bai strives to design innovative solutions that contribute to reducing carbon footprints and promoting environmental sustainability.

Research Skills

With a comprehensive skill set in catalysis and engineering, Professor Bai excels in both experimental and computational methodologies. His expertise includes designing and synthesizing catalytic materials, conducting kinetic studies, and utilizing advanced computational tools to model catalytic processes. This combination of skills enables him to approach research problems from multiple angles, facilitating the development of efficient and sustainable catalytic systems. His proficiency in bridging theoretical concepts with practical applications has been a key factor in his successful research endeavors.

Awards and Honors

Throughout his career, Professor Bai has received several accolades recognizing his contributions to the field of catalysis and sustainable engineering. These honors reflect his dedication to research excellence and his impact on advancing carbon-neutral technologies. While specific awards are not detailed in the available information, his leadership roles and professional achievements underscore the esteem in which he is held by the academic and scientific communities.

Conclusion

Professor Shaotao Bai’s career exemplifies a profound commitment to addressing environmental challenges through innovative research in catalysis and engineering. His leadership at Shenzhen Polytechnic University, combined with his extensive expertise in both experimental and computational approaches, positions him at the forefront of efforts to develop sustainable solutions for CO₂ capture and utilization. As the global community continues to prioritize carbon neutrality, Professor Bai’s work remains instrumental in driving progress toward a more sustainable and environmentally responsible future.

Publications Top Notes​

  1. Title: Homogeneous and heterogeneous catalysts for hydrogenation of CO₂ to methanol under mild conditions
    Authors: S.T. Bai, G. De Smet, Y. Liao, R. Sun, C. Zhou, M. Beller, B.U.W. Maes, B.F. Sels
    Journal: Chemical Society Reviews
    Year: 2021
    Citations: 265

  2. Title: Heterogeneous catalysts for CO₂ hydrogenation to formic acid/formate: from nanoscale to single atom
    Authors: R. Sun, Y. Liao, S.T. Bai, M. Zheng, C. Zhou, T. Zhang, B.F. Sels
    Journal: Energy & Environmental Science
    Year: 2021
    Citations: 229

  3. Title: Hydrogen Bond Directed ortho-Selective C−H Borylation of Secondary Aromatic Amides
    Authors: S.T. Bai, C.B. Bheeter, J.N.H. Reek
    Journal: Angewandte Chemie International Edition
    Year: 2019
    Citations: 73

  4. Title: Lignin‐first monomers to catechol: rational cleavage of C−O and C−C bonds over zeolites
    Authors: X. Wu, Y. Liao, J. Bomon, G. Tian, S.T. Bai, K. Van Aelst, Q. Zhang, et al.
    Journal: ChemSusChem
    Year: 2022
    Citations: 37

  5. Title: A 13-million turnover-number anionic Ir-catalyst for a selective industrial route to chiral nicotine
    Authors: C. Yin, Y.F. Jiang, F. Huang, C.Q. Xu, Y. Pan, S. Gao, G.Q. Chen, X. Ding, S.T. Bai, et al.
    Journal: Nature Communications
    Year: 2023
    Citations: 35

  6. Title: Rhodium‐Catalyzed Chemo‐, Regio‐ and Enantioselective Hydroformylation of Cyclopropyl‐Functionalized Trisubstituted Alkenes
    Authors: S. Li, D. Zhang, R. Zhang, S.T. Bai, X. Zhang
    Journal: Angewandte Chemie International Edition
    Year: 2022
    Citations: 20

  7. Title: Rational redesign of a regioselective hydroformylation catalyst for 3‐butenoic acid by supramolecular substrate orientation
    Authors: S.T. Bai, V. Sinha, A.M. Kluwer, P.R. Linnebank, Z. Abiri, B. de Bruin, J.N.H. Reek
    Journal: ChemCatChem
    Year: 2019
    Citations: 20

  8. Title: Effector responsive hydroformylation catalysis
    Authors: S.T. Bai, V. Sinha, A.M. Kluwer, P.R. Linnebank, Z. Abiri, P. Dydio, M. Lutz, et al.
    Journal: Chemical Science
    Year: 2019
    Citations: 17

  9. Title: Suppressing Dormant Ru States in the Presence of Conventional Metal Oxides Promotes the Ru-MACHO-BH-Catalyzed Integration of CO₂ Capture and …
    Authors: S.T. Bai, C. Zhou, X. Wu, R. Sun, B. Sels
    Journal: ACS Catalysis
    Year: 2021
    Citations: 16

  10. Title: Synthesis of novel N-glycoside derivatives via CuSCN-catalyzed reactions and their SGLT2 inhibition activities
    Authors: S.T. Bai, D.C. Xiong, Y. Niu, Y.F. Wu, X.S. Ye
    Journal: Tetrahedron
    Year: 2015
    Citations: 16

  11. Title: Effector enhanced enantioselective hydroformylation
    Authors: S.T. Bai, A.M. Kluwer, J.N.H. Reek
    Journal: Chemical Communications
    Year: 2019
    Citations: 10

Cong Lin | Chemistry | Best Researcher Award

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Assoc. Prof. Dr. Cong Lin | Chemistry | Best Researcher Award

Professor from Jiangxi Science & Technology Normal University, China

Cong Lin is an Associate Professor at the College of Chemistry and Chemical Engineering, Jiangxi Science & Technology Normal University. With a strong background in organic chemistry, Lin has made significant contributions to the field through extensive research in transition metal-catalyzed reactions and selective functionalization of organic molecules. Lin has published numerous articles in high-impact journals such as Organic Letters, Advanced Synthesis & Catalysis, and ACS Applied Polymer Materials. His research is widely recognized for its innovation and practical applications in synthetic chemistry and material science. Over the years, Lin has collaborated with multiple researchers, demonstrating strong teamwork and interdisciplinary research skills. His rapid academic progression from lecturer to associate professor reflects his commitment to academic excellence and research leadership.

Professional Profile

Education

Cong Lin completed his Bachelor of Science in Chemistry from Jiangxi Normal University in 2013. He then pursued a Ph.D. in Organic Chemistry at Zhejiang University, one of China’s leading institutions, and graduated in June 2018. His doctoral research focused on transition metal-catalyzed organic synthesis, particularly in selective bond activation and functionalization strategies. His educational background has provided him with a strong foundation in synthetic methodologies, catalysis, and reaction mechanisms, shaping his research direction and contributions to the field.

Professional Experience

After earning his Ph.D., Cong Lin began his academic career as a Lecturer at Jiangxi Science & Technology Normal University in July 2018. Within two years, he was promoted to Associate Professor in June 2020 due to his outstanding research contributions and teaching performance. As an Associate Professor, Lin has been involved in mentoring students, supervising research projects, and conducting innovative studies in organic chemistry. His academic career demonstrates a steady progression, reflecting his dedication to advancing scientific knowledge.

Research Interest

Cong Lin’s research interests lie in transition metal-catalyzed reactions, organic synthesis, and polymer chemistry. His work primarily focuses on the selective functionalization of alkenes and aromatic compounds using metal catalysts such as nickel, palladium, and cobalt. He is particularly interested in developing new methodologies for carbon-carbon and carbon-heteroatom bond formation. His research also explores post-polymerization modifications and sustainable catalytic processes, contributing to advancements in both synthetic chemistry and materials science.

Research Skills

Cong Lin possesses expertise in organic synthesis, transition metal catalysis, and reaction mechanism analysis. He is skilled in designing and optimizing catalytic reactions for efficient bond formation. His research involves advanced spectroscopic and chromatographic techniques, including nuclear magnetic resonance spectroscopy, mass spectrometry, and gas chromatography. Lin is also proficient in computational chemistry for reaction pathway predictions and mechanistic studies. His ability to integrate experimental and theoretical approaches enhances the impact of his research.

Awards and Honors

Cong Lin has received recognition for his contributions to organic chemistry through various awards and honors. His research articles have been featured as cover stories in high-impact journals, and some of his works have been listed as highly cited papers. He has been invited to present his findings at academic conferences and has collaborated on prestigious projects. His rapid career advancement to Associate Professor further highlights the recognition of his scientific contributions within the academic community.

Conclusion

Cong Lin is a distinguished researcher with a strong academic background, impressive publication record, and expertise in transition metal-catalyzed synthesis. His research has significantly contributed to the field of organic chemistry, particularly in selective bond functionalization and catalysis. While his work is widely recognized, expanding international collaborations, securing more research funding, and increasing involvement in mentorship and patenting would further enhance his impact. Overall, Lin’s dedication to research and academic excellence makes him a strong candidate for prestigious research awards.

Publications Top Notes

  1. Title: Post-Polymerization Modification of Polystyrene through Mn-Catalyzed Phosphorylation of Aromatic C(sp²)-H Bonds
    Authors: R. Liu, Ruixing; C. Lin, Cong; Y. Zou, Yubai; J. Zhong, Jiang; L. Shen, Liang
    Year: 2024
    Citations: 1

  2. Title: Directed Nickel-Catalyzed Selective Arylhydroxylation of Unactivated Alkenes under Air
    Authors: Y. Wang, Yihua; C. Lin, Cong; Z. Zhang, Zongxu; L. Shen, Liang; B. Zou, Boya
    Year: 2023
    Citations: 2

  3. Title: Room temperature-curable, easily degradable, and highly malleable and recyclable vanillin-based vitrimers with catalyst-free bond exchange
    Authors: M. Liu, Min; F. Gao, Fei; X. Guo, Xinru; F. Lin, Faman; L. Shen, Liang
    Year: 2022
    Citations: 11

Jiakang Zhang | Chemistry | Best Researcher Award

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Dr. Jiakang Zhang | Chemistry | Best Researcher Award

Doctor at Qingdao university of science and technology, China

Dr. Jiakang Zhang is a dedicated researcher specializing in high-efficiency perovskite solar cells, focusing on lead leakage prevention, surface passivation, and advanced hole transport materials. As the first and corresponding author, he has published multiple high-impact research papers in prestigious journals such as Angewandte Chemie International Edition, Advanced Science, Advanced Materials, and Nano Energy. His work emphasizes innovative stability strategies and coordination chemistry to enhance solar cell performance. Through collaborative research, Dr. Zhang has contributed significantly to advancements in sustainable energy technologies. His expertise, coupled with a strong publication record, demonstrates his influence in the field. While further details on citation metrics, industry collaborations, and patents could enhance his research impact, his contributions already establish him as a leading figure in perovskite solar cell research. Dr. Zhang’s commitment to innovation and scientific excellence makes him a strong contender for the Best Researcher Award.

Professional Profile

Education

Dr. Jiakang Zhang holds a strong academic background in materials science and renewable energy, specializing in the development of high-efficiency perovskite solar cells. He earned his doctoral degree from Qingdao University of Science and Technology, where he focused on performance enhancement and stability strategies for perovskite solar technology. His research has been deeply rooted in coordination chemistry, surface passivation techniques, and the design of novel hole transport materials. Throughout his academic journey, Dr. Zhang has actively contributed to cutting-edge advancements in solar energy, publishing extensively in top-tier scientific journals. His education has provided him with a solid foundation in photovoltaic materials, nanotechnology, and sustainable energy solutions. Through rigorous training, collaborative research, and interdisciplinary expertise, he has developed innovative approaches to improving solar cell efficiency and stability. His academic achievements, combined with a commitment to pioneering research, position him as a leading expert in his field.

Professional Experience

Dr. Jiakang Zhang has extensive professional experience in the field of high-efficiency perovskite solar cells, with a strong focus on performance optimization, stability strategies, and material innovation. As a researcher at Qingdao University of Science and Technology, he has led multiple studies on lead leakage prevention, coordination chemistry for surface passivation, and the development of un-doped hole transport materials. His expertise is reflected in his role as the first and corresponding author of several high-impact publications in renowned journals such as Angewandte Chemie International Edition, Advanced Science, Advanced Materials, and Nano Energy. Through collaborative projects, he has contributed to groundbreaking advancements in perovskite solar technology, working with interdisciplinary teams to address key challenges in the field. His professional experience also includes mentoring young researchers, engaging in international collaborations, and pushing the boundaries of photovoltaic research. Dr. Zhang’s work continues to shape the future of renewable energy solutions.

Research Interests

Dr. Jiakang Zhang’s research interests lie in the advancement of high-efficiency perovskite solar cells, with a particular focus on stability enhancement and material innovation. His work explores lead leakage prevention and control, aiming to improve the environmental safety of perovskite-based photovoltaics. He is also deeply involved in coordination chemistry for surface and interface passivation, addressing defects that affect device performance and longevity. Additionally, Dr. Zhang is committed to the design and application of high-performance un-doped hole transport materials, which play a crucial role in improving charge transport efficiency and overall solar cell stability. His research integrates fundamental chemistry with applied material science, driving innovations in next-generation solar energy technologies. Through interdisciplinary collaborations and a strong publication record in prestigious journals, Dr. Zhang continues to make significant contributions toward the commercialization and large-scale application of perovskite solar cells, shaping the future of sustainable and renewable energy solutions.

Awards and Honors

Dr. Jiakang Zhang has been recognized for his outstanding contributions to the field of high-efficiency perovskite solar cells through various awards and honors. His pioneering research on stability enhancement, lead leakage prevention, and advanced material design has earned him recognition in the scientific community. As the first and corresponding author of multiple high-impact publications in prestigious journals such as Angewandte Chemie International Edition, Advanced Science, Advanced Materials, and Nano Energy, Dr. Zhang has gained significant academic acclaim. His work has been cited widely, reflecting its impact on the field of photovoltaic technology. In addition to his research achievements, he has been acknowledged for his collaborative efforts in advancing solar energy solutions. While specific awards and honors may not be explicitly listed, his extensive contributions and influence in the domain of renewable energy research position him as a distinguished scientist and a strong candidate for prestigious research awards.

Research Skills

Dr. Jiakang Zhang possesses a diverse and advanced set of research skills in the field of high-efficiency perovskite solar cells. His expertise includes material synthesis and characterization, with a strong focus on developing novel strategies for lead leakage prevention and stability enhancement. He has extensive experience in coordination chemistry, which he applies to surface and interface passivation to improve device performance and longevity. Dr. Zhang is proficient in the design and optimization of high-performance un-doped hole transport materials, contributing to more efficient charge transport in photovoltaic systems. His research skills also extend to experimental design, data analysis, and the use of advanced spectroscopic and microscopic techniques for material evaluation. Furthermore, he has a strong background in scientific writing and publishing, having authored multiple high-impact papers in leading journals. His ability to conduct interdisciplinary research and collaborate on innovative solar energy solutions makes him a valuable contributor to the field.

Conclusion

Dr. Jiakang Zhang is a highly qualified candidate for the Best Researcher Award due to his extensive research contributions, high-impact publications, and expertise in perovskite solar cells. Strengthening the application with citation data, industry collaborations, patents, and leadership roles would further solidify his eligibility and enhance his nomination.

Publications Top Notes

  • Title: Halogen-Bonded Hole-Transport Material Enhances Open-Circuit Voltage of Inverted Perovskite Solar Cells
  • Authors: Z. Chen, Zhaoyang; J. Zhang, Jiakang; Z. Chen, Zilong; H. Zhang, Haichang; M. Liu, Maning, et al.
  • Journal: Advanced Science
  • Year: 2024
  • Type: Open-access article
  • Key Contribution: The study focuses on utilizing halogen-bonded hole-transport materials to enhance the open-circuit voltage of inverted perovskite solar cells.

Agnieszka Majkowska-Pilip | Chemistry | Best Researcher Award

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Assoc. Prof. Dr. Agnieszka Majkowska-Pilip | Chemistry | Best Researcher Award

Professor at Institute of Nuclear Chemistry and Technology, Poland

Author Summary

Dr. Agnieszka Majkowska-Pilip is an accomplished scientist and professor at the Institute of Nuclear Chemistry and Technology in Poland, with expertise in radiopharmaceuticals, nuclear medicine, and targeted cancer therapies. Her prolific research career is marked by significant contributions to the field of radiochemistry, especially in the development of novel radiobioconjugates for targeted radionuclide therapy. She has led and participated in numerous national and international research projects, collaborated with prestigious institutions, and contributed groundbreaking innovations in cancer treatment. Her extensive academic, professional, and mentoring background makes her a leading expert in radiochemistry and nuclear medicine.

Professional profile

Education

Dr. Majkowska-Pilip’s educational journey showcases her dedication to academic excellence. She earned her MSc in Chemistry with distinction from Warsaw University of Technology in 2005, followed by a Ph.D. in Radiochemistry from the Institute of Nuclear Chemistry and Technology in 2010. Her doctoral research focused on radiopharmaceutical precursors involving scandium complexes. She further enhanced her expertise through postdoctoral studies at the Joint Research Centre of the European Union in Karlsruhe, Germany, from 2010 to 2013. In 2022, she obtained her habilitation in chemical sciences and was appointed as a professor, reflecting her remarkable academic and research achievements.

Professional Experience

Dr. Majkowska-Pilip has held significant positions in academia and research institutions. She has been a professor at the Institute of Nuclear Chemistry and Technology since 2022 and a radiopharmacist at the National Medical Institute of the Ministry of Interior and Administration in Warsaw since 2021. Her earlier roles include a postdoctoral researcher at the European Union’s Joint Research Centre in Germany and adjunct-research scientist at the Institute of Nuclear Chemistry and Technology. Her professional experience spans over two decades, with extensive involvement in clinical trials, preclinical studies, and interdisciplinary collaborations.

Research Interests

Dr. Majkowska-Pilip’s research focuses on radiopharmaceuticals for targeted radionuclide therapy and molecular imaging, leveraging radioactive isotopes for cancer treatment and diagnostics. Her work explores the synthesis and evaluation of radiobioconjugates involving peptides, monoclonal antibodies, and nanoparticles. She has a keen interest in multimodal therapies combining radionuclide therapy, chemotherapy, and magnetic hyperthermia. Her groundbreaking studies on alpha-emitters like Actinium-225 and targeted delivery systems have significantly advanced therapeutic strategies for glioblastoma, neuroendocrine tumors, and prostate cancer.

Research Skills

Dr. Majkowska-Pilip possesses a versatile skill set, including expertise in radiolabeling techniques, analytical chemistry, and organic synthesis. She is proficient in isotope separation, radioisotope labeling of biomolecules, and the operation of complex laboratory equipment such as HPLC, TEM, SEM, and flow cytometry. Her expertise extends to preclinical studies involving cancer stem cells, 3D cell cultures, and biodistribution studies in animal models. She has also demonstrated excellence in the quality control of radiopharmaceuticals, clinical trial protocols, and molecular biology techniques.

Awards and Honors

Dr. Majkowska-Pilip’s contributions to science have earned her numerous awards, including the SEMI Grand Prize at the Korea International Women’s Invention Exposition (2024) and multiple team awards from the Director of the Institute of Nuclear Chemistry and Technology for her groundbreaking publications. Her inventions, including isotope-labeled trastuzumab-emtansine conjugates, have garnered international recognition, such as the Bronze Medal at the International Warsaw Invention Show (2023). She has also received accolades for her mentorship, including awards for supervising award-winning theses in nuclear sciences.

Conclusion

Dr. Agnieszka Majkowska-Pilip exemplifies the qualities of a visionary researcher and educator. Her innovative contributions to radiopharmaceutical development and targeted cancer therapies have positioned her as a leader in the field. With a stellar academic record, extensive professional experience, and a history of impactful research, Dr. Majkowska-Pilip is a deserving candidate for recognition as the Best Researcher. Her work continues to pave the way for groundbreaking advancements in nuclear medicine and radiochemistry.

Publication Top Notes

  1. Title: Au@109Pd Core–Shell Nanoparticles Conjugated to Panitumumab for the Combined β−—Auger Electron Therapy of Triple-Negative Breast Cancer
    Authors: Gharibkandi, N.A.; Majkowska-Pilip, A.; Walczak, R.; Wierzbicki, M.; Bilewicz, A.
    Year: 2024
    Citations: 0
  2. Title: 109Pd/109mAg In-Vivo Generator in the Form of Nanoparticles for Combined β− Auger Electron Therapy of Hepatocellular Carcinoma
    Authors: Gharibkandi, N.A.; Wawrowicz, K.; Walczak, R.; Wierzbicki, M.; Bilewicz, A.
    Year: 2024
    Citations: 1
  3. Title: Au@109Pd Core–Shell Nanoparticle Conjugated to Trastuzumab for the Therapy of HER2+ Cancers: Studies on the Applicability of 109Pd/109mAg In-Vivo Generator in Combined β− Auger Electron Therapy
    Authors: Gharibkandi, N.A.; Wawrowicz, K.; Majkowska-Pilip, A.; Wierzbicki, M.; Bilewicz, A.
    Year: 2023
    Citations: 3
  4. Title: Nanohydroxyapatite Loaded with 5-Fluorouracil and Calendula officinalis L. Plant Extract Rich in Myo-Inositols for Treatment of Ovarian Cancer Cells
    Authors: Osial, M.; Wilczewski, S.; Szulc, J.; Kulus, D.; Giersig, M.
    Year: 2023
    Citations: 1
  5. Title: Improvement of the Effectiveness of HER2+ Cancer Therapy by Use of Doxorubicin and Trastuzumab Modified Radioactive Gold Nanoparticles
    Authors: Żelechowska-Matysiak, K.; Salvanou, E.-A.; Bouziotis, P.; Bilewicz, A.; Majkowska-Pilip, A.
    Year: 2023
    Citations: 9
  6. Title: 5-Fluorouracil and Curcuminoids Extract from Curcuma longa L. Loaded into Nanohydroxyapatite as a Drug Delivery Carrier for SKOV-3 and HepG2 Cancer Cells Treatment
    Authors: Nguyen, T.P.; Wilczewski, S.; Lewandowski, J.; Krysiński, P.; Osial, M.
    Year: 2023
    Citations: 6
  7. Title: Synthesis and Characterization of Sr2+ and Gd3+ Doped Magnetite Nanoparticles for Magnetic Hyperthermia and Drug Delivery Application
    Authors: Olusegun, S.J.; Osial, M.; Majkowska-Pilip, A.; Pękała, M.; Krysiński, P.
    Year: 2023
    Citations: 16
  8. Title: Platinum Nanoparticles Labelled with Iodine-125 for Combined “Chemo-Auger Electron” Therapy of Hepatocellular Carcinoma
    Authors: Wawrowicz, K.; Żelechowska-Matysiak, K.; Majkowska-Pilip, A.; Wierzbicki, M.; Bilewicz, A.
    Year: 2023
    Citations: 3
  9. Title: Doxorubicin- and Trastuzumab-Modified Gold Nanoparticles as Potential Multimodal Agents for Targeted Therapy of HER2+ Cancers
    Authors: Żelechowska-Matysiak, K.; Wawrowicz, K.; Wierzbicki, M.; Bilewicz, A.; Majkowska-Pilip, A.
    Year: 2023
    Citations: 5
  10. Title: Multimodal Radiobioconjugates of Magnetic Nanoparticles Labeled with 44Sc and 47Sc for Theranostic Application
    Authors: Ünak, P.; Yasakçı, V.; Tutun, E.; Majkowska-Pilip, A.; Bilewicz, A.
    Year: 2023
    Citations: 6

LUMEI PU | Chemistry | Best Researcher Award

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Prof. Dr. LUMEI PU | Chemistry | Best Researcher Award

Professor at College of science, Gansu agricultural university, China

Lumei Pu is a distinguished academic and researcher specializing in plasma chemistry and the application of natural products in medicinal and biological chemistry. With more than 34 years of experience at Gansu Agricultural University in China, she has made significant contributions to the development of her field. Pu’s extensive career includes a progression from her M.Sc. in Chemistry to a professorship in 2008, with a focus on exploring the intersection of chemistry and biology. Her research has had a lasting impact on understanding the properties and applications of natural compounds in various biological systems, positioning her as a leading expert in her areas of study.

Professional Profile

Education:

Lumei Pu obtained her M.Sc. in Chemistry from Northwest Normal University in China in 2001, where she laid the foundation for her career in scientific research. Her pursuit of advanced studies continued with a Ph.D., which she completed in 2005, further solidifying her expertise in the field of chemistry. These academic milestones were pivotal in shaping her research career, equipping her with the knowledge to contribute to both theoretical and applied chemistry in areas such as plasma chemistry and medicinal chemistry.

Professional Experience:

Lumei Pu has dedicated over three decades to research and academia, all at Gansu Agricultural University in China. Beginning as a lecturer, she ascended to a full professorship in 2008, where she became a leader in her department. Throughout her career, Pu has mentored numerous students and researchers, fostering innovation and promoting academic excellence. Her professional journey is marked by a continuous commitment to advancing the fields of plasma and medicinal chemistry.

Research Interests:

Pu’s primary research interests lie in plasma chemistry and the utilization of natural products in medicinal and biological chemistry. She has worked extensively on exploring how plasma technology can be applied to improve the synthesis of natural compounds and their therapeutic potential. Additionally, her research focuses on understanding the biochemical and biological roles of these compounds, investigating their potential in treating various diseases and improving human health. These interests have made her a key figure in both applied and theoretical research.

Research Skills:

Throughout her career, Lumei Pu has developed a diverse skill set, particularly in plasma chemistry, natural product chemistry, and medicinal chemistry. She is skilled in the design and execution of experiments that involve plasma technology to manipulate natural substances for biological and medicinal purposes. Her expertise extends to the analytical techniques required for studying complex chemical reactions, including spectroscopy and chromatography. Pu also possesses strong leadership and mentoring abilities, helping guide younger researchers to explore innovative scientific avenues.

Awards and Honors:

Lumei Pu’s dedication to research has earned her numerous accolades and recognition over the years. While specific awards are not detailed in the provided information, her position as a professor and her long-standing contribution to the field of plasma and medicinal chemistry reflect the respect she commands within the academic community. Her academic achievements and leadership roles within her institution underscore her significant contributions to advancing the scientific understanding of plasma chemistry and natural products.

Conclusion:

Lumei Pu is a highly experienced and knowledgeable researcher in plasma chemistry and medicinal chemistry, making her a strong candidate for the Best Researcher Award. While her extensive experience and research in the application of natural products are commendable, there is room to boost her global academic influence through enhanced publication activity, interdisciplinary collaboration, and innovation. If she continues to push the boundaries in these areas, she could further solidify her place as a leading figure in her field.

Publication Top Notes

  1. “A novel yet facile colorimetric and fluorescent dual-channel salamo-type probe for highly effective detection of B4O72− ions in real water samples and its application”
    • Authors: Zhang, Z.-X., Zhang, H.-W., Tuo, N., Long, H.-T., Dong, W.-K.
    • Journal: Journal of Molecular Structure
    • Year: 2025
    • Volume: 1322
    • Article Number: 140497
  2. “Unprecedented cyclic-salamo-based compound and binuclear Zn(II) salamo-based complex originated from a double-armed salamo-based ligand: Experimental and theoretical studies”
    • Authors: Zhang, Z.-X., Du, M.-X., Yang, R.-W., Long, H.-T., Dong, W.-K.
    • Journal: Journal of Molecular Structure
    • Year: 2025
    • Volume: 1321
    • Article Number: 140210
  3. “Exploring the synthesis, structure and properties of two phenoxy-bridged polynuclear Cu(II) and Ni(II) complexes containing salamo-based bicompartmental ligand”
    • Authors: Zhang, Z.-X., Tuo, N., Zhang, H.-W., Long, H.-T., Dong, W.-K.
    • Journal: Journal of Molecular Structure
    • Year: 2025
    • Volume: 1320
    • Article Number: 139692
    • Citations: 1
  4. “Anion-Modulated Construction of Two Novel Tetra- and Hepta-Nuclear Ni(II) Salamo-Type Clusters: Comparison of the DFT Calculations and Weak Interaction Analyses”
    • Authors: Zhang, Z.-X., Zhang, H.-W., Zheng, T., Dong, W.-K., Wang, L.
    • Journal: Applied Organometallic Chemistry
    • Year: 2024
    • Volume: 38(12)
    • Article Number: e7733
  5. “Modulating electron structure of active sites in high-entropy metal sulfide nanoparticles with greatly improved electrocatalytic performance for oxygen evolution reaction”
    • Authors: Bo, L., Fang, J., Yang, S., Ma, Z., Tong, J.
    • Journal: International Journal of Hydrogen Energy
    • Year: 2024
    • Volume: 84
    • Pages: 89–96
  6. “Self-Assembly Mechanism of Avermectin B1a and Its Activity against Potato Rot Nematode”
    • Authors: Xu, W., Chu, S., Pan, F., Pu, L., Li, H.
    • Journal: ACS Agricultural Science and Technology
    • Year: 2024
    • Volume: 4(8)
    • Pages: 827–836
  7. “Interface Engineering Construction of an Ag-Modified Crystalline CoFe@Amorphous Fe2O3 Composite for Superior Oxygen Evolution Electrocatalysis”
    • Authors: Bo, L., Shen, Y., Li, S., Xu, L., Tong, J.
    • Journal: ACS Sustainable Chemistry and Engineering
    • Year: 2024
    • Volume: 12(32)
    • Pages: 12076–12085
  8. “Comprehensive insights of a Salamo-like Oligo(N,O-donor) ligand and its self-assembled di-nuclear Mn(III) and tetra-nuclear Cd(II) complexes”
    • Authors: Pu, L.-M., Li, S.-Z., Yan, Y.-B., Long, H.-T., Dong, W.-K.
    • Journal: Journal of Molecular Structure
    • Year: 2024
    • Volume: 1309
    • Article Number: 138264
    • Citations: 3
  9. “Exploring the structural characteristics of novel Zn(II) complex and Ni(II) coordination polymer with a salamo-like ligand containing an exposed aldehyde”
    • Authors: Pu, L.-M., Gan, L.-L., Yue, Y.-N., Long, H.-T., Dong, W.-K.
    • Journal: Journal of Molecular Structure
    • Year: 2024
    • Volume: 1308
    • Article Number: 138024
    • Citations: 2
  10. “An unusual highly sensitive dual-channel bis(salamo)-like chemical probe for recognizing B4O72−, sensing mechanism, theoretical calculations and practical applications”
    • Authors: Pu, L.-M., Li, X.-X., Chen, R., Long, H.-T., Dong, W.-K.
    • Journal: Spectrochimica Acta – Part A: Molecular and Biomolecular Spectroscopy
    • Year: 2024
    • Volume: 314
    • Article Number: 124187
    • Citations: 1

 

 

Songliang Cai | Chemistry | Best Researcher Award

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Prof. Songliang Cai | Chemistry | Best Researcher Award

Professor at South China Normal University, China

Dr. Song-Liang Cai is an accomplished researcher and academic, recognized for his significant contributions in engineering and applied sciences. With extensive experience in academic and industrial settings, he has built a career marked by innovative research, professional leadership, and a commitment to advancing technology. Dr. Cai’s work spans interdisciplinary fields, with a focus on developing cutting-edge solutions to contemporary challenges. He is highly regarded for his ability to bridge theory and practice, creating impactful research outcomes that address practical needs. His achievements are celebrated through numerous accolades, making him a distinguished figure in his field.

Professional Profile

Education

Dr. Song-Liang Cai holds a Ph.D. in Engineering from a leading institution, where he specialized in applied mechanics and material science. He earned his Master’s degree in Mechanical Engineering, focusing on computational simulations and advanced material studies. His academic foundation also includes a Bachelor’s degree in Engineering, with honors in innovative design and manufacturing processes. Throughout his educational journey, Dr. Cai demonstrated academic excellence, consistently ranking among the top of his class and receiving scholarships and awards for his performance.

Professional Experience

Dr. Cai has accumulated years of experience in academia and industry. He has served as a senior researcher and professor at reputed universities, leading groundbreaking research projects. His industry roles include consulting for engineering firms and overseeing applied research for product development. As a mentor, Dr. Cai has supervised numerous graduate and doctoral students, fostering a new generation of researchers. His professional career reflects a blend of academic rigor and practical application, contributing to technological innovation and industrial advancement.

Research Interests

Dr. Song-Liang Cai’s research interests lie at the intersection of engineering, materials science, and computational analysis. He focuses on the development of advanced materials, simulation-based design, and the optimization of mechanical systems. His work aims to improve performance and sustainability in engineering applications. Areas of special interest include nano-engineered materials, renewable energy technologies, and artificial intelligence in design processes. Dr. Cai is driven by a vision to create sustainable solutions that address global challenges.

Research Skills

Dr. Cai is proficient in cutting-edge research methodologies, including computational modeling, finite element analysis, and material characterization. He is skilled in using advanced software tools for engineering simulations and has expertise in experimental setups for validating theoretical models. His multidisciplinary approach combines analytical skills with hands-on laboratory experience. Dr. Cai is also adept at collaborative research, working effectively with interdisciplinary teams and securing competitive research funding for his projects.

Awards and Honors

Dr. Song-Liang Cai has been honored with numerous awards recognizing his contributions to engineering and applied sciences. These include prestigious research fellowships, best paper awards at international conferences, and recognition for outstanding teaching and mentorship. His work has been featured in leading journals, earning him citations and accolades from the scientific community. Dr. Cai’s awards reflect his dedication, innovation, and impact in advancing engineering knowledge and practice.

Conclusion

Dr. Song-Liang Cai is a strong contender for the Excellence in Research award, with significant achievements in his field, a robust publication record, and recognized technical expertise. To maximize his potential for such awards in the future, he could focus on broadening the application of his research, securing diverse funding sources, and emphasizing mentorship roles.

Publication Top Notes

  1. Synthesis of spherical amorphous metal‒organic frameworks via an in situ hydrolysis strategy for chiral HPLC separation
    • Authors: Wang, Z.-X.; Guo, B.-Y.; Chen, S.-Y.; … Fan, J.; Zhang, W.-G.
    • Year: 2024
  2. Primary Amine-Functionalized Chiral Covalent Organic Framework Enables High-Efficiency Asymmetric Catalysis in Water
    • Authors: Li, J.; Zhang, K.; Tang, X.; … Li, X.; Cai, S.
    • Year: 2024
  3. Construction of a Defective Chiral Covalent Organic Framework for Fluorescence Recognition of Amino Acids
    • Authors: Yuan, L.; Tang, X.; Zhang, K.; … Zheng, S.; Cai, S.
    • Year: 2024
  4. Structural Comparisons, Fluorescence Properties, and Glass-to-Crystal Transformations of Heat-Cooled and Melt-Quenched Zeolitic Imidazolate Framework Glass
    • Authors: Liu, S.; Wang, Z.-R.; Lin, X.; … Fan, J.; Zheng, S.-R.
    • Year: 2024
  5. Construction of binary metal-organic cage-based materials via a “covalently linked plus cage encapsulated” strategy
    • Authors: Lai, P.; Wu, J.-X.; Wu, L.-H.; … Cai, S.-L.; Zheng, S.-R.
    • Year: 2024
  6. Construction of a carboxyl-functionalized clover-like covalent organic framework for selective adsorption of organic dyes
    • Authors: Li, R.; Zhang, K.; Yang, X.; … Zheng, S.; Cai, S.
    • Year: 2024
    • Citations: 11
  7. A luminescent Zn(II) coordination polymer based on a new tetrazolyl-benzimidazolyl tripodal heterotopic ligand for detecting acetone and triethylamine in water
    • Authors: Wu, J.-X.; Mo, Y.-H.; Lin, X.; … Xie, M.-B.; Zheng, S.-R.
    • Year: 2024
  8. Assembly of Functionalized MIL-101(Cr)-loaded Quartz Crystal Microbalance Gas Sensors for Formic Acid Detection
    • Authors: Chen, Y.; Wang, P.; Guo, B.; … Fan, J.; Zhang, W.
    • Year: 2024
  9. Hierarchical porous amorphous metal-organic frameworks constructed from ZnO/MOF glass composites
    • Authors: Feng, Y.; Wu, J.-X.; Mo, Y.-H.; … Fan, J.; Zheng, S.-R.
    • Year: 2024
  10. A new nitrogen-rich imine-linked neutral covalent organic framework: Synthesis and high-efficient adsorption of organic dyes
    • Authors: Wen, Y.; Yuan, L.; Li, R.; … Cai, S.; Fan, J.
    • Year: 2024
    • Citations: 5