Jinzeng Wang | Optical properties of Lanthanide contained compounds | Best Researcher Award 

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Assoc Prof Dr. Jinzeng Wang | Optical properties of Lanthanide contained compounds | Best Researcher Award 

Shanxi Normal University | China


AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Assoc. Prof. Dr. Jinzeng Wang began his academic journey with a Ph.D. in Inorganic Chemistry from the Institut National des Sciences Appliquées Rennes (INSA Rennes, France) in 2020, where he studied under the guidance of Professor Olivier Guillou. His doctoral research focused on the synthesis and characterization of luminescent lanthanide-contained coordination polymers and hybrid compounds, which laid a strong foundation for his future research endeavors.

PROFESSIONAL ENDEAVORS

After completing his Ph.D., Dr. Wang joined the School of Chemistry and Materials Science at Shanxi Normal University in 2021 as an Assistant Professor. Demonstrating remarkable expertise and dedication, he was promoted to Associate Professor in 2023. His professional journey at Shanxi Normal University has been marked by significant contributions to both teaching and research, particularly in the field of inorganic chemistry.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Wang's primary research focus is on the design, synthesis, and application of luminescent lanthanide-contained coordination polymers and hybrid compounds. His work in this area has led to the publication of over 20 research articles in prestigious journals, including the Chemical Engineering Journal, Results in Physics, Inorganic Chemistry Frontiers, and Inorganica Chimica Acta. His research is known for advancing the understanding of the optical properties of lanthanide-contained compounds, which have numerous applications in various fields such as lighting, sensing, and bioimaging.

IMPACT AND INFLUENCE

Dr. Wang's research has significantly impacted the field of inorganic chemistry, particularly in the study of the optical properties of lanthanide-contained compounds. His innovative approaches to synthesizing these materials have opened new avenues for their application in advanced technologies. His work has been widely cited in academic literature, reflecting his influence and the importance of his contributions to the scientific community.

ACADEMIC CITATIONS

Dr. Wang's publications are highly regarded in the academic community, as evidenced by their frequent citations. His research on luminescent lanthanide-contained compounds has been particularly influential, providing valuable insights into their optical properties and potential applications. This recognition underscores the high quality and relevance of his work.

LEGACY AND FUTURE CONTRIBUTIONS

Looking ahead, Dr. Wang aims to continue his pioneering research on the optical properties of lanthanide-contained compounds. His future work will likely focus on developing new materials with enhanced luminescent properties and exploring their practical applications in various technological fields. Dr. Wang's ongoing contributions are expected to further solidify his legacy as a leading researcher in inorganic chemistry and inspire future advancements in the study of luminescent materials.

OPTICAL PROPERTIES OF LANTHANIDE CONTAINED COMPOUNDS 

Throughout his career, Dr. Wang has emphasized the significance of optical properties of lanthanide-contained compounds in his research. These keywords encapsulate his dedication to understanding and enhancing the luminescent characteristics of these materials, which are crucial for their application in cutting-edge technologies. His work in this area continues to drive innovation and excellence in inorganic chemistry, ensuring his place at the forefront of scientific research.

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Tianlei Zhang | Physical chemistry | Best Researcher Award

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Prof. Tianlei Zhang | Physical chemistry | Best Researcher Award 

Shaanxi University of Technology | China

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Prof. Tianlei Zhang graduated from Shaanxi Normal University in June 2013, majoring in physical chemistry. During his early academic career, he demonstrated a strong foundation in the principles of physical chemistry, which set the stage for his later research endeavors. His rigorous academic training equipped him with the necessary skills and knowledge to tackle complex problems in the field of atmospheric chemistry and microdynamic mechanisms.

PROFESSIONAL ENDEAVORS

Throughout his professional career, Prof. Zhang has been involved in several high-profile research projects. He has been the recipient of one youth project (21603132) and one upper-level project (22073059) from the National Natural Science Foundation of China. Additionally, he secured a project (2019JM-336) from the Natural Science Foundation of Shaanxi Province and an industrial development project from the Department of Education of Shaanxi Province. His professional work focuses on the atmospheric behavior of chemical species, the interactions at the air-water interface, and the nucleation of reaction products, which are central themes in physical chemistry.

CONTRIBUTIONS AND RESEARCH FOCUS

Prof. Zhang's research employs a theoretical approach that combines quantum chemistry and first-principles molecular dynamics simulation. This methodology has been pivotal in simulating the physicochemical microreaction mechanisms and kinetics-related properties of Criegee intermediates and nitrogen/sulfur oxides in both the gas phase and at the air-water interface. His studies reveal how water molecules and acid/base molecules influence these microreaction mechanisms, providing insights into longstanding scientific questions. This research is significant in the field of physical chemistry, particularly in understanding the fundamental processes that occur in atmospheric chemistry.

IMPACT AND INFLUENCE

In the past five years, Prof. Zhang has published 25 SCI research papers in mainstream journals as the first or corresponding author, including one top-tier SCI Region I paper and 16 SCI Region II papers. His work has contributed significantly to the understanding of microdynamic mechanisms and chemical processes at the molecular level. The impact of his research is reflected in the numerous citations and recognition he has received from the scientific community. His findings have advanced the field of physical chemistry and provided a deeper understanding of atmospheric chemical processes.

ACADEMIC CITATIONS

Prof. Zhang's extensive publication record and the high citation rate of his papers underscore the influence of his research in the scientific community. His studies on the involvement of water molecules and acid/base molecules in microreaction mechanisms have been widely cited, highlighting their importance in resolving complex chemical interactions in atmospheric systems. These contributions are a testament to his expertise and the value of his work in physical chemistry.

LEGACY AND FUTURE CONTRIBUTIONS

Looking forward, Prof. Zhang aims to continue his research on the microdynamic mechanisms of atmospheric chemical reactions. His future work will likely delve deeper into the interactions at the air-water interface and the role of various molecules in these processes. Through his innovative approaches and dedication to uncovering fundamental chemical processes, Prof. Zhang is poised to leave a lasting legacy in the field of physical chemistry, contributing to advancements in environmental chemistry and molecular dynamics.

PHYSICAL CHEMISTRY 

Prof. Zhang's research revolves around key concepts in physical chemistry such as atmospheric behavior, air-water interface interactions, product nucleation, chemical processes, and microdynamic mechanisms. These keywords encapsulate the essence of his work and highlight the interdisciplinary nature of his research, bridging the gap between theoretical studies and practical applications in atmospheric chemistry.

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Yongfu Liang | fluorescence | Best Researcher Award 

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Dr. Yongfu Liang | fluorescence | Best Researcher Award 

Zhengzhou University of Light Industry | China

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Yongfu Liang's academic journey began in Henan Province, China, where he developed a strong foundation in material sciences. He completed his B.Sc. graduation thesis on "Research on Circularly Polarized Beam Splitter" under the supervision of Prof. Guancheng Sun. This early research laid the groundwork for his interest in optical materials and their applications. He furthered his studies with a Master’s and Ph.D. thesis titled "Pressure-Regulated Crystal Structure and Photoelectric Properties of Typical Organic-Inorganic Hybrid Perovskites," supervised by Prof. Tian Cui and Prof. Xiaoli Huang. This work significantly contributed to the understanding of material properties under varying pressure conditions, emphasizing their electronic and photoelectric characteristics.

PROFESSIONAL ENDEAVORS

Currently, Yongfu Liang is affiliated with Zhengzhou University of Light Industry in Henan, China. His role at the university involves both teaching and conducting advanced research in materials science. He has developed extensive experimental skills, particularly in ultra-low temperature technologies using Diamond Anvil Cells (DAC). His expertise includes four-electrode resistance and superconductivity measurements, as well as gas liquefaction packaging technology in DAC. These skills are crucial for exploring materials in extreme environments, enhancing the understanding of their electronic properties and phase transformations.

CONTRIBUTIONS AND RESEARCH FOCUS

Yongfu Liang's research focuses on the properties of materials under high-pressure conditions and extreme environments. His work involves using a variety of high-pressure experimental techniques with in-house facilities, such as Raman spectroscopy, infrared absorption and reflection spectra, UV-visible absorption spectrum, X-ray diffraction, and impedance measurement. These techniques allow for detailed analysis of materials, contributing to advancements in fluorescence studies. His research has practical implications for the development of new materials with unique electronic and optical properties.

IMPACT AND INFLUENCE

Yongfu Liang’s research has significantly impacted the field of materials science, particularly in the study of fluorescence. His innovative use of high-pressure techniques has led to a deeper understanding of material behaviors in extreme environments. This knowledge is essential for the development of advanced materials for electronic and photonic applications. His contributions have been recognized through numerous citations, reflecting the influence and importance of his work in the scientific community.

ACADEMIC CITATIONS

The academic community has recognized Yongfu Liang’s contributions through extensive citations. His publications in high-impact journals and conference presentations highlight the relevance and significance of his research on fluorescence and other material properties. These citations underscore his influence in advancing the understanding of how materials behave under extreme conditions.

LEGACY AND FUTURE CONTRIBUTIONS

Yongfu Liang’s legacy in materials science is marked by his innovative research and comprehensive understanding of materials under extreme conditions. His future contributions are expected to further explore the intersection of high-pressure environments and material properties, particularly focusing on fluorescence. His work promises to drive advancements in electronic materials, phase transformations, and structure refinement, continuing to impact both academic research and practical applications in the field.

FLUORESCENCE

Throughout his career, Yongfu Liang has significantly contributed to the field of fluorescence. His research has provided new insights into the behavior of materials under high-pressure conditions, revealing unique electronic and optical properties. By employing advanced experimental techniques and scientific programming tools such as Origin, GSAS, Zview, RefFIT, Vesta, and Material Studio, he has been able to conduct detailed and impactful studies. His dedication to understanding fluorescence in materials has positioned him as a key figure in this area of research, promising continued advancements and discoveries.

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