Ziyuan Liu | Spectroscopy | Best Researcher Award

Dr. Ziyuan Liu | Spectroscopy | Best Researcher Award 

Zhejiang Agriculture and Forestry University | China

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Dr. Ziyuan Liu's academic journey began at Changchun University of Science and Technology, where he earned his Bachelor of Science in Optoelectronic Technology from 2011 to 2015. He continued his studies at the same university, pursuing a Ph.D. in optics, which he completed in December 2021. This solid academic foundation set the stage for his future contributions to the field of optics and materials science.

PROFESSIONAL ENDEAVORS

In January 2022, Dr. Liu joined Zhejiang A & F University as a lecturer. His professional career has been marked by a strong focus on research and teaching in advanced optical technologies. He has developed a robust portfolio of research, particularly in the areas of material detection using Laser-Induced Breakdown Spectroscopy (LIBS) and Raman Spectroscopy, the fabrication and characterization of micro-nano structures with femtosecond lasers, and advancements in machine vision and machine learning.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Liu's research has led to significant advancements in the field of optics. He has focused on material detection using Spectroscopy, specifically LIBS and Raman Spectroscopy. His work on the temperature-dependent wetting characteristics of micro-nano structured metal surfaces formed by femtosecond lasers has been published in the Journal of Materials Science. He has also investigated the effects of frost formation on the ice adhesion of micro-nano structure metal surfaces, contributing valuable insights published in the Journal of Colloid and Interface Science.

IMPACT AND INFLUENCE

Dr. Liu's research has had a profound impact on the understanding and practical applications of Spectroscopy and micro-nano structures. His work on anisotropic ice adhesion of micro-nano structured metal surfaces using femtosecond lasers has been recognized in Langmuir. His innovative approach to the small-sample stacking model for qualitative analysis of aluminum alloys using femtosecond laser-induced breakdown spectroscopy was published in Optics Express. Additionally, his contributions to Fourier ptychographic layer-based imaging of hazy environments were featured in Results in Physics.

ACADEMIC CITATIONS

Dr. Liu's research has been widely cited in academic circles, reflecting the high regard in which his work is held. His studies on Spectroscopy and micro-nano structures have garnered significant attention, leading to a deeper theoretical understanding and practical advancements in these fields. His extensive publication record includes 17 papers, highlighting his substantial contributions to optical technology and material science.

LEGACY AND FUTURE CONTRIBUTIONS

Dr. Liu's legacy in the field of optics and materials science is marked by his dedication to advancing the frontiers of knowledge through rigorous research and innovative applications. His future contributions are expected to further enhance the capabilities of Spectroscopy, particularly in the detection and analysis of materials. As a lecturer and researcher, Dr. Liu continues to inspire and mentor the next generation of scientists, ensuring a lasting impact on the field.

SPECTROSCOPY 

Dr. Liu's work prominently features the keywords Spectroscopy, femtosecond lasers, and micro-nano structures. His research in Spectroscopy has led to significant advancements in material detection and analysis, showcasing the critical role of this technology in modern science. The integration of femtosecond lasers in his work has enabled precise fabrication and characterization of micro-nano structures, further demonstrating the innovative nature of his research.

NOTABLE PUBLICATION

Bienvenu Mbanga | Spectroscopy | Innovation in Atomic Research Award

Dr. Bienvenu Mbanga | Spectroscopy | Innovation in Atomic Research Award 

Nelson Mandela University | South Africa 

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Dr. Bienvenu Mbanga began his academic journey with a Bachelor of Science degree from the University of South Africa in 2013, majoring in Chemistry and Mathematics, with additional studies in Physics, Statistics, and English. He furthered his education with a BSc Honours in Chemistry from the University of Johannesburg in 2014, focusing on Analytical Chemistry with a mini dissertation on leachate characterization for pollution assessment. He continued his studies at the University of Johannesburg, earning a Master’s degree in Chemistry in 2016, where he conducted research on the provenance determination of rooibos tea using stable isotope ratio analysis. In 2021, he completed his PhD in Chemistry at the same institution, specializing in the collection and analysis of water samples, development of nanomaterials, and identifying their chemical compositions and properties.

PROFESSIONAL ENDEAVORS

Dr. Mbanga’s professional career is marked by several key positions. He currently serves as a Postdoctoral Fellow at Nelson Mandela University since February 2022. His responsibilities include the collection and analysis of agricultural waste and wastewater samples, preparation and characterization of novel nanomaterials, manuscript writing, lab management, and development of new water treatment techniques. Prior to this, he worked as a teacher at Union High School and a Chemistry Facilitator at Glenvista High School, where he was involved in overseeing academic activities and providing guidance to students. Additionally, he served as a Research Assistant at the University of Johannesburg, where he gained extensive experience in water sample collection, nanomaterial development, and analytical techniques.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Mbanga’s research focuses on the development of nanomaterials and their practical applications, particularly in water treatment. His work involves using spectroscopy to identify the chemical compositions and properties of these materials. His contributions include innovative approaches to avoid secondary pollution in water treatment processes and the preparation of novel nanomaterials. Dr. Mbanga’s research has significant implications for environmental sustainability and pollution control.

IMPACT AND INFLUENCE

Dr. Mbanga’s contributions to the field of nanomaterials and water treatment have had a notable impact on environmental science. His expertise in spectroscopy has allowed him to develop advanced methods for analyzing and improving water quality. His work has been recognized with several awards and honors, including being selected as a judge for the third Commonwealth Chemistry poster competition, among the 100 brightest minds in Africa, and a Scimart Africa mentee.

ACADEMIC CITATIONS

Dr. Mbanga’s research has been widely cited in scientific literature, demonstrating his influence in the field of chemistry and nanomaterials. His work on spectroscopy and its applications in environmental science has been referenced by numerous researchers, reflecting the importance and relevance of his findings.

LEGACY AND FUTURE CONTRIBUTIONS

Dr. Mbanga’s legacy lies in his significant contributions to the development of nanomaterials and their applications in environmental science. His future work is expected to continue advancing the field, particularly in the use of spectroscopy for water treatment and pollution control. His dedication to academic excellence and research innovation ensures that his contributions will have a lasting impact on the scientific community and environmental sustainability.

SPECTROSCOPY 

Dr. Mbanga’s research prominently features the keywords spectroscopy, nanomaterials, and water treatment. His focus on spectroscopy techniques is central to his work, highlighting the critical role this concept plays in his research. The integration of these keywords underscores the importance of spectroscopy in advancing our understanding and application of nanomaterials in environmental science.

NOTABLE PUBLICATION

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