Masoud Shahrokhi | Physical Chemistry | Best Researcher Award

Dr. Masoud Shahrokhi | Physical Chemistry | Best Researcher Award 

Institut Charles Gerhardt Montpellier | France

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Dr. Masoud Shahrokhi's academic journey began with a Bachelor of Science (B.Sc.) in Physics, which he completed in 2007 with a GPA of 17.05 out of 20. He pursued his Master of Science (M.Sc.) in Condensed Matter Physics from 2008 to 2011, focusing on the investigation of magnetic and electric properties of halfmetal MnAs in the interface of MnAs/GaSb and InP nanolayers. His impressive GPA of 18.26 out of 20 reflects his dedication and academic excellence. Dr. Shahrokhi continued to excel in his Ph.D. in Condensed Matter Physics, which he completed from 2011 to 2014, with a thesis on Zinc oxide and Beryllium oxide Nanostructures, achieving an outstanding GPA of 19.68 out of 20.

PROFESSIONAL ENDEAVORS

Dr. Shahrokhi has accumulated extensive experience through various prestigious research positions. He is currently a Research Associate at ICGM, University of Montpellier, France, where he works on supported catalytically active liquid metal solutions (SCALMS) using AIMD and DFT. Previously, he served as a Postdoctoral Researcher at IFP Energies nouvelles in Lyon, France, focusing on the reactivity of supported platinum-based nanoclusters investigated by DFT. His other notable roles include postdoctoral research positions at École normale supérieure de Lyon, Razi University, Institut Català d’Investigació Química (ICIQ) in Spain, and University of Paris-Est, Paris. His research at these institutions involved predicting the optoelectronic properties of 2D and 3D layered materials, novel optoelectronic 2D materials, catalytic materials, and multiscale chemo-mechanical modeling of graphene-coated materials.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Shahrokhi's research contributions are significant and diverse, primarily focusing on the electronic structures of nanomaterials (metal clusters, surfaces) and their catalytic and thermodynamic properties. His expertise extends to the evolution of model catalysts at finite temperatures and reactive gas studies using advanced theoretical methods. His research also delves into reactivity in catalysis and photocatalysis, particularly excited state studies. His notable work in Physical Chemistry has been pivotal in advancing the understanding of material properties and their applications in various fields.

IMPACT AND INFLUENCE

Dr. Shahrokhi's impact on the scientific community is profound, as evidenced by his inclusion in the World Ranking of Top 2% Scientists (2021-2023) by the Elsevier Data Repository. His contributions to Physical Chemistry and material science have been recognized through various awards, including the National Elite Foundation Award of Iran and the Marie Curie–COFUND fellowship at ICIQ, Spain. His research findings have been widely cited, reflecting the high relevance and influence of his work.

ACADEMIC CITATIONS

Dr. Shahrokhi's work has been extensively cited in academic journals, highlighting the significance of his contributions to Physical Chemistry and computational material science. He has served as a journal referee for numerous prestigious journals, including Carbon, Applied Surface Science, Journal of Materials Chemistry C, Surface Science, and many others, further establishing his authority and expertise in the field.

LEGACY AND FUTURE CONTRIBUTIONS

Dr. Shahrokhi's legacy in the field of computational material science is marked by his innovative research and significant contributions to Physical Chemistry. His future contributions are expected to continue bridging academia and industry, leveraging his expertise in multiscale modeling and theoretical methods to drive impactful advancements in material science. As a versatile Ph.D. in computational material science, Dr. Shahrokhi's work will undoubtedly continue to influence and inspire future research and applications in the field.

PHYSICAL CHEMISTRY 

Dr. Shahrokhi's research prominently features the keywords Physical Chemistry, electronic structures, nanomaterials, catalytic properties, and thermodynamic properties. His work in Physical Chemistry explores the intricate details of material behavior at the nanoscale, providing valuable insights into their potential applications in catalysis and other fields. The integration of these keywords in his research underscores the depth and breadth of his expertise, cementing his contributions to the advancement of Physical Chemistry and material science.

NOTABLE PUBLICATION

Tianlei Zhang | Physical chemistry | Best Researcher Award

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.

NOTABLE PUBLICATION