Ahmad Ranjbar | Density Functional Theory | Best Researcher Award

Dr. Ahmad Ranjbar | Density Functional Theory | Best Researcher Award 

University of Paderborn | Germany 

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Dr. Ahmad Ranjbar's academic journey began with a Bachelor's degree in Physics from Ferdowsi University of Mashhad, where he graduated with distinction. He then pursued a Master's degree in Condensed Matter Physics at Sharif University of Technology, focusing on first-principles calculations of many-body states for single nitrogen-vacancy defects in diamond. His PhD in Materials Science & Engineering from Tohoku University further honed his expertise, with a thesis on hydrogen adsorption on carbon-based materials, specifically applied to magnetism and energy storage.

PROFESSIONAL ENDEAVORS

Dr. Ranjbar has held several prestigious positions throughout his career. He is currently a Guest Scientist at the University of Paderborn, Germany, where he implements hybrid machine learning models and discovers novel materials. His previous roles include being a Research Scientist at Technische Universität Dresden and a Project Engineer at Steinbeis-Forschungszentrum quantUP, where he focused on computational investigations of gas sensors and numerical modeling of sputter deposition processes. His extensive experience also includes a Senior Research Scientist role at the University of Paderborn and a Postdoctoral Researcher position at RIKEN Center for Computational Science, where he conducted in-depth first-principles DFT investigations.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Ranjbar’s research is centered on Density Functional Theory (DFT) and its applications in materials science. His work includes developing functional materials for energy harvesting, storage, and photocatalysis. He has conducted pioneering research on MAX phases and 2D MXenes, exploring their electronic, magnetic, and quantum transport characteristics. His contributions also extend to the study of topological insulators, magnetic topological insulators, and gas sensors, where he has applied high-throughput computational screening and hybrid machine learning models.

IMPACT AND INFLUENCE

Dr. Ranjbar's work in Density Functional Theory and computational materials science has significantly influenced the field. His research on the catalytic activity of various phases of NiS2, the discovery of topological insulator materials, and the development of photocatalysts have been widely recognized. His ability to integrate machine learning with traditional computational methods has advanced the understanding and prediction of material properties, impacting both academic research and practical applications in energy and sensor technologies.

ACADEMIC CITES

Throughout his career, Dr. Ranjbar has authored numerous publications in high-impact journals. His expertise in Density Functional Theory and materials science has led to significant citations, highlighting the importance and relevance of his work. His research on 2D MXenes, photocatalytic materials, and gas sensors has been extensively cited, reflecting his contributions to advancing computational techniques and material innovations.

LEGACY AND FUTURE CONTRIBUTIONS

Dr. Ahmad Ranjbar's legacy is built upon his groundbreaking research in computational materials science and Density Functional Theory. His innovative approaches to integrating machine learning with first-principles modeling techniques have set new standards in the field. As he continues his work, Dr. Ranjbar is expected to make further advancements in the development of new materials for energy applications and sensor technologies. His commitment to education and collaboration ensures that his contributions will continue to influence future generations of scientists.

DENSITY FUNCTIONAL THEORY

Central to Dr. Ranjbar’s work is Density Functional Theory, a powerful computational method used to investigate the electronic structure of materials. His proficiency in DFT has enabled significant discoveries in various domains, including topological materials, MXenes, and gas sensors. Dr. Ranjbar’s expertise in DFT not only contributes to the theoretical understanding of material properties but also drives practical innovations in material design and application, underscoring the critical role of this theory in modern materials science.

NOTABLE PUBLICATION

Shilie Pan | Nonlinear Optical Crystal Materials | Best Researcher Award

Prof. Shilie Pan | Nonlinear Optical Crystal Materials | Best Researcher Award 

Xinjiang Technical Institute of Physics and Chemistry | China

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Prof. Shilie Pan was born on October 10, 1973, in China. He completed his Bachelor’s and Master’s degrees at Zhengzhou University between 1992 and 1999. He then pursued a Doctor of Philosophy degree at the University of Science and Technology of China, graduating in 2002. His early academic pursuits laid a strong foundation in crystal materials and Nonlinear optical crystal materials areas in which he would later achieve significant recognition and contribute extensively to the field.

PROFESSIONAL ENDEAVORS

Prof. Pan began his professional career as a post-doctoral fellow at the Technical Institute of Physics & Chemistry, Chinese Academy of Sciences, working in the laboratory of Prof. Chuangtian Chen from 2002 to 2004. He then moved to the USA to work as a post-doctoral fellow at Northwestern University under Prof. Kenneth R. Poeppelmeier from 2004 to 2007. Since 2007, he has served as a Professor at the Xinjiang Technical Institute of Physics and Chemistry, Chinese Academy of Sciences, and in 2021, he became the Director of the institute. His professional endeavors have focused on the synthesis, growth, and application of Nonlinear optical crystal materials.

CONTRIBUTIONS AND RESEARCH FOCUS

Prof. Pan’s research focuses on Nonlinear optical crystal materials, emphasizing their design, structural prediction, synthesis, and growth. His work integrates artificial intelligence with experimental synthesis and the study of physical properties to develop advanced optical devices. Prof. Pan has published over 500 peer-reviewed papers, cited more than 14,000 times, and holds 9 authorized US patents and 75 Chinese patents. His notable patents include innovations in ammonium fluoroborate and cesium fluoroborate nonlinear optical crystals, demonstrating his significant contributions to the field of Nonlinear optical crystal materials.

IMPACT AND INFLUENCE

Prof. Pan is recognized as one of the world’s top 10,000 scientists according to the Global Scholar database and has been a Chinese highly cited scholar by Elsevier from 2020 to 2022. His work has garnered numerous awards, including the Science and Technology Award of Xinjiang Province (First Class) in multiple years, the Chinese Overseas Chinese Contribution Award, and the National Science Fund for Distinguished Young Scholars. His influence extends through his role as an excellent tutor and mentor, earning awards for his exceptional guidance from the Chinese Academy of Sciences. His research on Nonlinear optical crystal materials has significantly advanced technological applications in lasers, optical communication, and medical treatment.

ACADEMIC CITES

Prof. Pan’s extensive publication record and patents have made a substantial impact on the scientific community. His research is widely cited, reflecting the importance and relevance of his work in Nonlinear optical crystal materials. The development of new electro-optical crystals and their applications in various technological fields highlight his role as a leading researcher and innovator.

LEGACY AND FUTURE CONTRIBUTIONS

Prof. Pan's legacy in the field of Nonlinear optical crystal materials is marked by his pioneering research, significant technological advancements, and exceptional mentorship. His future contributions are anticipated to further enhance the understanding and application of crystal materials in innovative optical devices. As he continues to lead research at the Xinjiang Technical Institute of Physics and Chemistry, his work will undoubtedly influence the next generation of scientists and the evolution of advanced optical technologies.

NONLINEAR OPTICAL CRYSTAL MATERIALS

Prof. Pan’s expertise in Nonlinear optical crystal materials encompasses the design and synthesis of new crystal structures, growth of electro-optical crystals, and development of optical devices. His patents on ammonium and cesium fluoroborate nonlinear optical crystals are testament to his innovative approach and profound impact in this specialized field. His research bridges theoretical predictions with practical applications, driving advancements in laser technology and optical communications. Prof. Pan’s work continues to shape the future of Nonlinear optical crystal materials and their applications in various high-tech industries.

NOTABLE PUBLICATION