Mahdy Elmahdy | Broadband Dielectric Spectroscopy | Atomic and Molecular Physics Innovation Award

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Prof. Mahdy Elmahdy | Broadband Dielectric Spectroscopy | Atomic and Molecular Physics Innovation Award

Prince Sattam bin Abdulaziz University | Saudi Arabia 

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Prof. Mahdy Elmahdy's academic journey began with a Bachelor of Science (B.Sc.) in Physics from Mansoura University, Egypt, awarded in May 1996. He continued his studies at the same institution, obtaining a Master of Science (M.Sc.) in Experimental Physics on April 29, 2002. His commitment to advancing his knowledge in experimental physics led him to pursue a Doctor of Philosophy (Ph.D.) at the University of Ioannina, Greece. He completed his Ph.D. on March 31, 2008, with a focus on Experimental Physics.

PROFESSIONAL ENDEAVORS

Prof. Elmahdy's career spans multiple prestigious institutions and roles. Currently, he serves as an Associate Professor at the Physics Department, College of Science & Humanity Studies, Prince Sattam Bin Abdulaziz University, Alkharj, Kingdom of Saudi Arabia, since February 5, 2019. Additionally, he holds a Professorship at the Physics Department, Faculty of Science, Mansoura University, Egypt, since January 27, 2021. His previous positions include Associate Professor at Mansoura University and various postdoctoral research roles in Germany, such as at the Leibniz-Institute for Polymer Research Dresden and the University of Leipzig.

CITATIONS

  • Citations  858
  • h-index    17
  • i10-index 20

CONTRIBUTIONS AND RESEARCH FOCUS

Prof. Elmahdy’s research primarily revolves around Broadband Dielectric Spectroscopy, a technique used to study the dielectric properties of materials across a broad frequency range. His contributions include significant work in experimental physics and the application of Broadband Dielectric Spectroscopy to understand material behaviors. His research involves studying complex materials and their dielectric properties, contributing to the broader field of material science and physics.

IMPACT AND INFLUENCE

Prof. Elmahdy's work with Broadband Dielectric Spectroscopy has had a profound impact on understanding the dielectric properties of various materials. His research has advanced the field by providing deeper insights into material behaviors and interactions at different frequencies. This work has influenced both theoretical and applied aspects of material science, enhancing knowledge in areas such as material characterization and processing.

ACADEMIC CITATIONS

Prof. Elmahdy’s research contributions, particularly in Broadband Dielectric Spectroscopy, are well-regarded in the academic community. His work has been cited in various scientific journals and conferences, reflecting its significance in advancing the understanding of material properties. His involvement in peer-review assignments for numerous prestigious journals further underscores the impact of his research.

LEGACY AND FUTURE CONTRIBUTIONS

Prof. Elmahdy’s legacy in the field of experimental physics is marked by his extensive research and contributions to Broadband Dielectric Spectroscopy. His future contributions are expected to further explore and refine dielectric spectroscopy techniques, continuing to enhance the understanding of material behaviors and properties. By advancing these methodologies, Prof. Elmahdy aims to leave a lasting impact on both theoretical research and practical applications in material science.

BROADBAND DIELECTRIC SPECTROSCOPY 

Prof. Elmahdy's work prominently features the keywords BROADBAND DIELECTRIC SPECTROSCOPY, experimental physics, and material science. His research on BROADBAND DIELECTRIC SPECTROSCOPY focuses on studying material properties across a wide frequency range, contributing significantly to the field. The integration of these keywords highlights the central role of BROADBAND DIELECTRIC SPECTROSCOPY in his research and its impact on advancing material science methodologies.

NOTABLE PUBLICATION

Dr. Muhammad Moin | Material science | Young Scientist Award 

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Dr. Muhammad Moin | Material science | Young Scientist Award 

University of Engineering and Technology Lahore | Pakistan

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Dr. Muhammad Moin's academic journey began with secondary education at Government High School, Pakpttan, where he completed his Secondary School Certificate in 2011. He then pursued Intermediate studies at Abaid Ullah Educational Complex Higher Secondary School, Pakpttan, graduating in 2013. Dr. Moin obtained his Bachelor's degree in Physics from the University of the Punjab, Lahore, Pakistan, from July 2013 to October 2015. His academic quest continued with an M.Phil. in Nano Science and Technology from the University of Engineering and Technology (UET), Lahore, Pakistan, which he completed from November 2015 to December 2019. During this period, Dr. Moin engaged deeply in research related to Material Science.

PROFESSIONAL ENDEAVORS

Dr. Moin has amassed significant experience in the field of Material Science through his role as a Research Scientist at the University of Engineering and Technology Lahore. He worked at this position from October 2020 to December 2022, where he contributed to research involving Density Functional Theory (DFT) and computational simulations using Material Studio software. His expertise includes methods such as General Gradient Approximation (GGA) and Hybrid Functional (HSEO6, HSEO3), and tools like WIEN2k. Dr. Moin's hands-on experience extends to working with CVD (Chemical Vapor Deposition) and centrifugation machines, further showcasing his practical skills in Material Science.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Moin's research primarily focuses on Material Science, emphasizing computational simulations and theoretical modeling. His work involves advanced techniques in Density Functional Theory (DFT) and computational simulations, which are critical for understanding material properties and behavior. His research contributes to the development and enhancement of materials through methods such as General Gradient Approximation (GGA) and Hybrid Functional (HSEO6, HSEO3). Dr. Moin's involvement in the application of CVD and centrifugation techniques further underscores his commitment to advancing Material Science.

IMPACT AND INFLUENCE

Dr. Moin's contributions to Material Science have impacted both theoretical and practical aspects of the field. His use of sophisticated computational methods and simulation tools has provided valuable insights into material properties and behaviors. His work with advanced techniques like DFT and Hybrid Functional methods has influenced ongoing research and development in Material Science. By leveraging his expertise in CVD and centrifugation techniques, Dr. Moin has contributed to the practical application of material science principles, enhancing the understanding and development of new materials.

ACADEMIC CITATIONS

Dr. Moin's research contributions in Material Science are supported by his academic work and practical applications. Although specific citations are not listed, his research activities, particularly in computational simulations and advanced material processing techniques, are likely to be referenced by peers in the field. His contributions to understanding material properties and behaviors through sophisticated methods and tools reflect his academic and professional impact.

LEGACY AND FUTURE CONTRIBUTIONS

Dr. Moin's legacy in Material Science is marked by his dedication to advancing the field through computational simulations and experimental techniques. His future contributions are expected to further explore and refine material science methodologies, particularly in the application of DFT and advanced simulation techniques. By continuing to innovate in the development and processing of new materials, Dr. Moin aims to make significant advancements in Material Science, leaving a lasting impact on both theoretical research and practical applications.

MATERIAL SCIENCE 

Dr. Moin's research prominently features the keywords Material Science, Density Functional Theory (DFT), computational simulations, General Gradient Approximation (GGA), Hybrid Functional (HSEO6, HSEO3), and CVD (Chemical Vapor Deposition). His work in Material Science involves applying these advanced techniques and tools to understand and enhance material properties, contributing to the broader field of material development and innovation. The integration of these keywords highlights the significance of Dr. Moin's research and its impact on advancing material science methodologies.

NOTABLE PUBLICATION

Masoud Shahrokhi | Physical Chemistry | Best Researcher Award

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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

Aditya Sahu | Quantum watermarking | Best Researcher Award

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Dr. Aditya Sahu | Quantum watermarking | Best Researcher Award 

Amrita University | India 

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Dr. Aditya Kumar Sahu began his academic journey with a Bachelor of Technology (B. Tech) in Information Technology from Gandhi Institute of Engineering & Technology (G.I.E.T), Gunupur, under B.P.U.T, Rourkela, Orissa, in 2007. He continued his education by earning a Master of Technology (M. Tech) in Computer Science from Majhigharini Institute of Technology and Science (MITS), Rayagada, affiliated with Berhampur University, Berhampur, Orissa, in 2011. Dr. Sahu further advanced his academic credentials by completing his Doctor of Philosophy (Ph.D.) in Computer Science & Engineering from KL University, Vijayawada, in June 2020. His doctoral thesis, titled "Development of Higher Embedding Capacity and Lower Distortion Image Steganography Techniques Using the Principles of LSB, LSB Matching, PVD, and Modulus Function," is accessible via Shodhganga.

PROFESSIONAL ENDEAVORS

Dr. Sahu has over 13 years of extensive teaching and research experience in the field of Computer Science & Engineering. He is currently an Associate Professor in the Department of Computer Science & Engineering at Vignan University, Guntur, Andhra Pradesh, a position he has held since October 2021. Before this role, he served as an Assistant Professor at GMRIT, Rajam, Andhra Pradesh, from June 2017 to October 2021. Dr. Sahu also held the position of Assistant Professor at KL University, Vijayawada, from June 2015 to May 2017, and at MITS, Rayagada, from April 2012 to May 2015. Additionally, he has experience as a Senior Lecturer at GATE, Berhampur, Odisha, and as a Lecturer at MITS, Rayagada.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Sahu's research focuses on image steganography, specifically the development of techniques that enhance embedding capacity and reduce distortion. His notable work in this area is encapsulated in his Ph.D. thesis, which explores advanced steganographic methods using LSB, LSB Matching, PVD, and Modulus Function principles. His research interests extend to the emerging field of Quantum Watermarking, where he aims to innovate secure and efficient methods for digital watermarking using quantum computing principles.

IMPACT AND INFLUENCE

Dr. Sahu's contributions to the field of Computer Science & Engineering have been widely recognized. He was listed in the World's Top 2% Scientists in 2021 by Elsevier and Stanford University. This acknowledgment underscores his influence and the high impact of his research on the global scientific community. His work in image steganography and Quantum Watermarking has been cited by peers, reflecting the significance and relevance of his research contributions.

ACADEMIC CITATIONS

Dr. Sahu's research has garnered significant academic citations, highlighting the scholarly impact of his work. His publications and contributions to the field of Quantum Watermarking have been widely referenced, indicating the importance of his innovative approaches in digital watermarking and image steganography.

LEGACY AND FUTURE CONTRIBUTIONS

Dr. Sahu's legacy is marked by his dedication to advancing the field of Computer Science & Engineering through innovative research and teaching. His future contributions are expected to further explore and expand the applications of Quantum Watermarking, providing new methodologies and solutions for digital security. As an accomplished researcher and educator, Dr. Sahu continues to inspire and mentor the next generation of computer scientists, ensuring a lasting impact on the field.

QUANTUM WATERMARKING 

Dr. Sahu's research prominently features the keywords Quantum Watermarking, image steganography, and digital security. His work in Quantum Watermarking explores the intersection of quantum computing and digital watermarking, aiming to develop advanced techniques that leverage quantum principles for enhanced security and efficiency. The integration of these keywords in his research highlights the innovative and cutting-edge nature of his academic pursuits, solidifying his contributions to the advancement of digital security technologies.

NOTABLE PUBLICATION

Sapna Baluni | Nonlinear dynamics | Best Researcher Award

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Ms. Sapna Baluni | Nonlinear dynamics | Best Researcher Award 

Chandigarh University Luckow campus | India  

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Ms. Sapna Baluni began her academic journey at Hemwati Nandan Bahuguna Garhwal University, where she earned her B.Sc. in Physics, Chemistry, and Mathematics from July 2013 to May 2016. She continued her studies at the same institution, completing her M.Sc. in Mathematics from August 2016 to May 2018. Ms. Baluni then pursued her Ph.D. in Nonlinear Dynamics and Synchronization of Neural Networks at the Indian Institute of Technology (BHU), Varanasi, under the supervision of Prof. Subir Das. Her doctoral research, completed in May 2024, focused on Nonlinear Dynamics, emphasizing Synchronization of Neural Networks and the application of advanced mathematical techniques in this domain.

PROFESSIONAL ENDEAVORS

Ms. Baluni currently serves as an Assistant Professor in Mathematical Sciences at Chandigarh University, Lucknow Campus, India, since June 2024. Her role involves teaching courses and conducting research in her areas of expertise. Prior to this, she completed her doctoral studies at IIT (BHU) Varanasi, where she actively engaged in research related to Nonlinear Dynamics and Synchronization of Neural Networks. Her academic journey is marked by her involvement in various workshops and conferences, where she has shared her knowledge and contributed to discussions on Nonlinear Dynamics and its applications.

CONTRIBUTIONS AND RESEARCH FOCUS

Ms. Baluni's research contributions focus on Nonlinear Dynamics, Stability Analysis, Synchronization, and Neural Networks. Her work explores complex mathematical models and their applications in understanding dynamic systems. She has participated in numerous workshops and conferences, including those on Nonlinear Applied Analysis, Dynamical Systems, and Computational Mathematics. Her research in Nonlinear Dynamics and related fields has provided valuable insights into system stability and synchronization, contributing to the advancement of mathematical sciences.

CITATIONS

  • Citations  33
  • h-index    3
  • i10-index 1

IMPACT AND INFLUENCE

Ms. Baluni's work in Nonlinear Dynamics and Synchronization of Neural Networks has had a notable impact on the field of mathematical sciences. Her research has been presented at various international conferences, highlighting her contributions to understanding complex dynamic systems. Her expertise in Nonlinear Dynamics is evident through her active participation in relevant workshops and conferences, reflecting the significance and influence of her work in advancing the field.

ACADEMIC CITATIONS

Ms. Baluni's research has been recognized and cited in academic circles, underscoring the relevance of her work in Nonlinear Dynamics. Her participation in high-profile conferences and workshops demonstrates the scholarly impact of her research. The citations and recognition of her work reflect the importance of her contributions to the field and the influence she has had on advancing knowledge in Nonlinear Dynamics and related areas.

LEGACY AND FUTURE CONTRIBUTIONS

Ms. Baluni's legacy is defined by her dedication to advancing the field of Nonlinear Dynamics through innovative research and academic contributions. Her future work is expected to further explore the complexities of dynamic systems and contribute to the development of new methodologies in Nonlinear Dynamics. As an emerging expert in her field, Ms. Baluni continues to inspire future researchers and contribute to the ongoing advancement of mathematical sciences.

NONLINEAR DYNAMICS 

Ms. Baluni's research prominently features the keywords Nonlinear Dynamics, Synchronization, and Neural Networks. Her work in Nonlinear Dynamics explores complex systems and their behavior, while her focus on Synchronization addresses the coordination of dynamic systems. The integration of these keywords in her research highlights the core themes of her academic pursuits and underscores her contributions to understanding and advancing the field of Nonlinear Dynamics.

NOTABLE PUBLICATION

  • Synchronization of Hypercomplex Neural Networks with Mixed Time-Varying Delays
    • Authors: Baluni, S., Yadav, V.K., Das, S., Cao, J.
    • Journal: Cognitive Computation
    • Year: 2024
  • Lagrange Stability Criteria for Hypercomplex Neural Networks with Time Varying Delays
    • Authors: Baluni, S., Yadav, V.K., Das, S.
    • Journal: Communications in Nonlinear Science and Numerical Simulation
    • Year: 2024
  • Function Projective Mittag-Leffler Synchronization of Non-Identical Fractional-Order Neural Networks
    • Authors: Baluni, S., Yadav, V.K., Das, S., Cao, J.
    • Journal: Physica Scripta
    • Year: 2024
  • Quasi Projective Synchronization of Time Varying Delayed Complex Valued Cohen-Grossberg Neural Networks
    • Authors: Baluni, S., Yadav, V.K., Das, S.
    • Journal: Information Sciences
    • Year: 2022
  • Lagrange α-Exponential Synchronization of Non-Identical Fractional-Order Complex-Valued Neural Networks
    • Authors: Baluni, S., Das, S., Yadav, V.K., Cao, J.
    • Journal: Circuits, Systems, and Signal Processing
    • Year: 2022

Meilan Pan | Environmental remediation | Best Researcher Award

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Dr. Meilan Pan | Environmental remediation | Best Researcher Award 

Zhejing University of Technology | China 

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Dr. Meilan Pan embarked on her academic journey at Nankai University in Tianjin, China, where she completed her Ph.D. in Environmental Engineering from 2013 to 2018. During her doctoral studies, she focused on electrochemical technologies for environmental remediation. She then moved to Nanyang Technological University in Singapore, where she worked as a Research Fellow in the School of Chemical and Biomedical Engineering from August 2018 to October 2020. Her research during this period primarily involved developing advanced electrochemical methods for energy conversion and environmental applications. Currently, Dr. Pan is a Full Professor at the College of Environment at Zhejiang University of Technology, China, a position she has held since November 2020.

PROFESSIONAL ENDEAVORS

Throughout her career, Dr. Pan has held significant research and academic positions. At Nanyang Technological University, she contributed to innovative research projects focusing on electrochemical technologies. Her work in Singapore laid the foundation for her current role at Zhejiang University of Technology, where she leads cutting-edge research in environmental remediation and energy conversion. Dr. Pan has been involved in several notable projects funded by prestigious organizations, such as the National Natural Science Foundation of China, which supports her work on piezocatalytic composites for heavy metal complex removal. Additionally, she has secured funding for projects on membrane distillation for lithium recovery from seawater and the development of intelligent inspection modules.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Pan's research contributions are extensive and impactful. She has published numerous articles in high-impact journals, covering topics like piezocatalysis for heavy metal complexes, electrochemical filtration, and the degradation of environmental pollutants. Her work on piezocatalytic composites has significantly advanced the field of environmental remediation, offering new methods for efficient pollutant degradation. Her research also extends to energy applications, with studies on membrane distillation and the recovery of valuable resources from seawater. Dr. Pan's innovative approaches and methodologies have positioned her as a leading researcher in both environmental and energy-related fields.

CITATIONS

  • Citations  758
  • indice h    13
  • indice i10 18

IMPACT AND INFLUENCE

Dr. Pan's research has had a profound impact on the field of environmental remediation. Her studies on the degradation of complex pollutants and the development of advanced filtration methods have provided valuable insights and practical solutions for tackling environmental challenges. Her work has been widely cited, reflecting the influence and relevance of her contributions. The application of her research findings extends to various industries, including water treatment and resource recovery, demonstrating the broad applicability and significance of her work.

ACADEMIC CITATIONS

Dr. Pan's extensive publication record includes numerous high-impact articles that have been widely cited in the academic community. Her research on environmental remediation has provided a solid foundation for further studies and advancements in the field. Her work on piezocatalytic composites, in particular, has garnered significant attention, highlighting her role in pioneering innovative solutions for environmental challenges. The frequent citations of her work underscore her influence and the critical role her research plays in advancing scientific knowledge and practical applications in environmental science.

LEGACY AND FUTURE CONTRIBUTIONS

Dr. Pan's legacy is marked by her dedication to advancing the field of environmental remediation through innovative research and practical applications. Her future contributions are expected to further enhance the understanding and implementation of advanced technologies for pollutant degradation and resource recovery. As a leading figure in her field, Dr. Pan continues to inspire and guide new generations of researchers, ensuring the ongoing development and application of her groundbreaking work.

ENVIRONMENTAL REMEDIATION 

Dr. Pan's research in environmental remediation has consistently focused on developing and applying advanced technologies for the degradation of pollutants and the recovery of valuable resources. Her innovative approaches to environmental remediation have significantly advanced the field, providing new insights and practical solutions for tackling complex environmental challenges. The keywords environmental remediation encapsulate the core of her research and its broad impact on science and industry.

NOTABLE PUBLICATION

Rutam Biswal | Graphene Quantum Dots | Young Scientist Award

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Ms. Rutam Biswal | Graphene Quantum Dots | Young Scientist Award 

University of Allahabad | India 

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Ms. Rutam Biswal demonstrated academic excellence from a young age, excelling in her high school and intermediate studies under the Central Board of Secondary Education (CBSE) in India. She completed her high school in 2012 with a stellar CGPA of 10, and her intermediate studies in 2014 with an impressive 96% in major subjects including Biology, Chemistry, Physics, English, and Hindi. She pursued her undergraduate studies at Banaras Hindu University, earning a B.Sc. (Hons.) in Chemistry with a CGPA of 8.92 in 2017. Continuing her passion for chemistry, Ms. Biswal completed her M.Sc. in Chemistry (Analytical Chemistry specialization) from the same university in 2019 with a CGPA of 8.93. She is currently pursuing her Ph.D. in Material Sciences at the University of Allahabad.

PROFESSIONAL ENDEAVORS

Throughout her academic journey, Ms. Biswal has engaged in various diploma and certificate courses to expand her knowledge and skills. She has completed several online non-credit courses from prestigious institutions such as the University of Manchester, Johns Hopkins University, Nanyang Technological University, and the University of California, Davis. These courses covered diverse topics including molecular spectroscopy, chemicals and health, forensic science, materials science, thermodynamics, and nanotechnology. Ms. Biswal has also excelled in language proficiency, obtaining a high grade in the Indian Language Test for Odia.

CONTRIBUTIONS AND RESEARCH FOCUS

Ms. Biswal's research focus lies in the field of Material Sciences, with a particular emphasis on Graphene Quantum Dots. Her research involves designing and characterizing nanomaterials, as evidenced by her internship at Banaras Hindu University, where she worked on a project entitled “Designing and Characterization of Nanoparticle Organic Hybrid Material.” She has also participated in the CSTUP Summer Research Fellowship Programme. Ms. Biswal's expertise in Graphene Quantum Dots is further demonstrated through her coursework and research projects, highlighting her contributions to the field of nanotechnology and materials science.

IMPACT AND INFLUENCE

Ms. Biswal's academic achievements have earned her numerous awards and recognitions. She has consistently been a top performer, securing the highest marks in various exams and competitions. Notable awards include the Kalpana Chawla Award of Science in 2012, the SHE (Scholarship for Higher Education) under DST INSPIRE from 2014 to 2019, and the "Young Scientist Award" in the International Research Awards on Science, Technology, and Management in 2022. Her research on Graphene Quantum Dots has garnered attention and accolades, reflecting her significant impact in the scientific community.

ACADEMIC CITATIONS

Ms. Biswal's contributions to the field of Material Sciences are well-cited, indicating the relevance and influence of her research. Her work on Graphene Quantum Dots is frequently referenced by peers and scholars, underlining the importance of her findings in advancing the understanding of nanomaterials. Her publications and research projects serve as valuable resources for those exploring similar topics in materials science and nanotechnology.

LEGACY AND FUTURE CONTRIBUTIONS

Ms. Biswal's legacy in the field of Material Sciences is marked by her dedication to research and academic excellence. As she continues her Ph.D. studies and expands her research on Graphene Quantum Dots, she is poised to make further significant contributions to the scientific community. Her future work is expected to enhance the understanding of nanomaterials and their applications, solidifying her position as a leading researcher in the field. Ms. Biswal's commitment to education and research will undoubtedly leave a lasting impact, inspiring future generations of scientists and researchers.

NOTABLE PUBLICATION

Taras Radchenko | Electronic properties | Best Researcher Award 

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Dr. Taras Radchenko | Electronic properties | Best Researcher Award 

G. V. Kurdyumov Institute for Metal Physics, National Academy of Sciences of Ukraine | Ukraine

 AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Dr. Taras Radchenko embarked on his academic journey at Cherkasy State University, where he earned a Specialist Diploma in Physics and Mathematics with Honours in 1997. He continued at the same institution, obtaining a Master’s Degree in Physics with Honours in 2000. Dr. Radchenko pursued further studies as a postgraduate student at the Institute for Metal Physics of the NAS of Ukraine from 2000 to 2003, where he completed his Ph.D. thesis on May 6, 2003. His dissertation focused on diffusional phase transformations in alloys and solid solutions, emphasizing electronic properties. He was awarded a Ph.D. in Physical and Mathematical Sciences in November 2003. Dr. Radchenko later achieved the status of Senior Research Scientist in 2009 and earned his Doctor of Sciences degree in 2015, further establishing his expertise in the field.

PROFESSIONAL ENDEAVORS

Dr. Radchenko has a distinguished career in academia and research. He began as a Teacher of Physics and Mathematics at Teklyne School and later taught Informatics and Industrial Automation at Cherkasy Vocational School #17. He joined the G.V. Kurdyumov Institute for Metal Physics of the NAS of Ukraine in 2002 as a Junior Staff Research Scientist and progressively advanced to positions of Staff Research Scientist, Senior Staff Research Scientist, Leading Staff Research Scientist, and eventually Head of Department in 2021. Dr. Radchenko's roles involved significant research contributions, particularly in the study of electronic properties of materials. Additionally, he has served on the editorial boards of several scientific journals, including roles as Executive Secretary and Deputy Editor-in-Chief.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Radchenko’s primary research interests lie in diffusional phase transformations in alloys, solid solutions, and nanoscale systems. His work encompasses statistical thermodynamics, kinetics, and computational modeling of electronic properties in these materials. He has also delved into statistical physics, condensed matter theory, and the study of order-disorder phase transformations, point and line defects, and the electronic properties of graphene and related 2D materials. His research on the structural, electronic, and transport properties of these materials has been pivotal in advancing the understanding of their behavior under various conditions. Dr. Radchenko's recent projects have included studying the magnetic phase α″-Fe16N2 and investigating the effects of strain and defects on the conductivity of 2D materials.

IMPACT AND INFLUENCE

Dr. Radchenko’s work has significantly impacted the fields of materials science and condensed matter physics, particularly in understanding the electronic properties of various materials. His research has been supported by numerous grants and projects, including NATO Reintegration Grants, grants from the National Academy of Sciences of Ukraine, and joint research projects with international partners. These projects have facilitated important collaborations and advancements in the study of nanoscale systems and materials science. Dr. Radchenko’s contributions have been recognized through several awards, including scholarships from the National Academy of Sciences of Ukraine, the World Federation of Scientists, and the Kyiv Mayor for intellectually gifted youth.

ACADEMIC CITATIONS

Dr. Radchenko’s extensive research has been widely cited in the academic community, reflecting the significance and influence of his work. His studies on phase transformations, statistical thermodynamics, and electronic properties of materials have provided valuable insights and have been foundational for subsequent research in these areas. His publications continue to serve as key references for scientists and researchers exploring similar topics.

LEGACY AND FUTURE CONTRIBUTIONS

Dr. Radchenko aims to continue his pioneering research in the field of materials science, with a focus on exploring new materials and their electronic properties. His future contributions are expected to further enhance the understanding of complex material behaviors and their applications in various technologies. Dr. Radchenko's legacy will be marked by his dedication to advancing scientific knowledge and his influential role in mentoring the next generation of researchers.

ELECTRONIC PROPERTIES 

Dr. Radchenko's work on electronic properties has been central to his research, particularly in understanding the behavior of materials at the nanoscale. His findings on the electronic properties of graphene, 2D materials, and other nanoscale systems have significantly contributed to the field of materials science. The keywords electronic properties encapsulate the core of his research and highlight the impact of his work on the scientific community.

NOTABLE PUBLICATION

Jose Luis Cuevas Figueroa | Quantum Materials | Best Researcher Award

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Dr. Jose Luis Cuevas Figueroa | Quantum Materials | Best Researcher Award 

Universidad Indoamérica | Mexico 

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Dr. José Luis Cuevas Figueroa began his academic journey with a Bachelor of Science in Communications and Electronics Engineering from the National Polytechnic Institute, completed in 2006. He then pursued a Master of Science in Communications and Electronics from the same institution, focusing on the electronic properties of semiconductor nanostructures, and graduated in 2009. His master’s thesis explored "Oxygen effects on the electronic properties in SiC nanowires hydrogenated kind β," marking the beginning of his profound interest in quantum materials. He earned his Ph.D. in Communications and Electronics, specializing in Material Science and Nanotechnology, from the National Polytechnic Institute in 2013. His doctoral research further delved into the intricate electronic properties of semiconductor nanostructures, cementing his expertise in the field.

PROFESSIONAL ENDEAVORS

Dr. Cuevas Figueroa has built an illustrious career marked by significant teaching and research roles. From 2014 to 2016, he was a Postdoctoral Fellow at the Metropolitan Autonomous University (UAM), where he conducted groundbreaking research on the design and development of TiO2 nanoparticles doped with copper using the sol-gel method. His work aimed at treating difficult diseases such as cancer and epilepsy. He also taught the subject "nanobiomaterials" to medical students, providing a scientific perspective on the topic. From 2017 to 2019, he served as a Nanotechnology Professor at Yachay Tech University, where he taught various subjects including Physics I and II, introduction to engineering, and nanobiomaterials. His experimental research at Yachay Tech focused on creating new oxide nanomaterials with bactericidal effects and studying the electronic properties and chemical stability of ZnO triangular nanowires doped with chitosan using DFT methodology.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Cuevas Figueroa’s research contributions are centered on the electronic properties of semiconductor nanostructures and the development of nanomaterials with advanced functionalities. His work on quantum materials includes the study of electronic properties and chemical stability of various nanostructures using Density Functional Theory (DFT) methodology. He has published numerous articles in high-impact journals, advancing the understanding of how doping and structural modifications affect the behavior of quantum materials. His innovative research on TiO2 and SiC nanostructures has opened new avenues for their application in medical and technological fields.

IMPACT AND INFLUENCE

Dr. Cuevas Figueroa’s research has had a significant impact on the field of quantum materials, particularly in understanding the electronic properties and stability of semiconductor nanostructures. His findings have contributed to the development of new materials with potential applications in treating diseases and in electronic devices. His work has been recognized by prestigious awards and grants from CONAHCyT, including the Level I National System of Researchers distinction from 2014 to 2023 and multiple scholarships for his doctoral and postdoctoral research.

ACADEMIC CITATIONS

Dr. Cuevas Figueroa’s research has been widely cited in the academic community, reflecting the importance and influence of his contributions to quantum materials. His studies on TiO2 and SiC nanostructures have been referenced by researchers exploring similar materials and applications, demonstrating the far-reaching impact of his work. His publications provide critical insights into the electronic properties and potential uses of these materials, solidifying his reputation as a leading researcher in the field.

LEGACY AND FUTURE CONTRIBUTIONS

Dr. Cuevas Figueroa aims to continue his pioneering work in quantum materials, focusing on the development and application of advanced nanostructures. His future contributions are expected to further enhance the understanding and utilization of these materials in various scientific and industrial applications. His legacy will be marked by his dedication to advancing the field of nanotechnology and his influence on both current and future generations of researchers and students.

QUANTUM MATERIALS 

Dr. Cuevas Figueroa’s expertise in quantum materials has positioned him as a key figure in the study of electronic properties and chemical stability of semiconductor nanostructures. His innovative approaches and findings in quantum materials research have significantly advanced the field, contributing to both theoretical knowledge and practical applications. The keywords quantum materials encapsulate the core of his research and its impact on science and technology.

NOTABLE PUBLICATION

Abdellah Tahiri | molecular dynamics | Atomic and Molecular Physics Innovation Award 

Posted on by AMO Physics

Prof. Abdellah Tahiri | molecular dynamics | Atomic and Molecular Physics Innovation Award 

Faculty of science dhar el mehraz university sidi mohamed ben abdellah fez | Morocco 

AUTHOR PROFILE

EARLY ACADEMIC PURSUITS

Prof. Abdellah Tahiri began his academic journey with a Baccalauréat in Sciences expérimentale from Lycée 06 novembre El Jadida in 1998. He then earned a Licence Fondamental in Science de la Matière Physique with a specialization in Réseaux et télécoms from Université Choaib Doukkali, El Jadida, Faculté des Sciences in 2002. He followed this with professional training, obtaining a certificat de la qualification pédagogique from Center Régional Derb Galef in 2003. Prof. Tahiri completed his Master’s in Informatique scientifique en physique des hautes énergies et expérimentales from Université Hassan II-Casablanca, Faculté des Sciences Ain Chock in 2009. His academic pursuits culminated in earning a Doctorat in physiques appliquée et Sciences des matériaux from the faculté des sciences Ben M’sik, Université Hassane II Casablanca in January 2021. His doctoral research focused on the "Etude des propriétés mécaniques et structurales de Tungstène nanocristallin par la méthode de dynamique moléculaire," supervised by Brahim Boubeker.

PROFESSIONAL ENDEAVORS

Prof. Tahiri has built a distinguished career in applied physics and material sciences. His professional experience includes significant research and teaching positions at various prestigious institutions. Since earning his doctorate, he has continued his research within the Laboratoire d’Ingénierie et Matériaux (LIMAT). His professional endeavors have focused on utilizing molecular dynamics simulations and the Embedded Atom Method (EAM) to explore the mechanical properties and structural behaviors of nanocrystalline tungsten under various conditions.

CONTRIBUTIONS AND RESEARCH FOCUS

Prof. Tahiri’s primary research interests include studying the mechanical and structural properties of nanocrystalline tungsten through molecular dynamics simulations. His work has extensively covered various mechanical tests, such as compression, nano-indentation, and uniaxial tension. He has developed models of tungsten with grain sizes ranging from 4 to 15 nm using Voronoi construction tools. His research has yielded significant insights into the elastic coefficients of tungsten at different temperatures and grain sizes, including Young’s modulus, shear modulus, compressibility, Poisson's ratio, and anisotropy.

In addition to the study of tungsten, Prof. Tahiri has explored the effects of temperature and rhenium (Re) concentrations in W1‑xRex alloys on their shear elastic modulus. His findings have been compared with existing literature, achieving highly satisfactory agreement.

IMPACT AND INFLUENCE

Prof. Tahiri's research in molecular dynamics has had a profound impact on the field of material science, particularly in understanding the mechanical properties of nanocrystalline tungsten. His work has contributed valuable knowledge on the behavior of materials at the nanoscale, influencing further research and applications in nanotechnology and material engineering. His studies on the deformation processes of nanocrystalline tungsten and the inverse Hall-Petch effect have been particularly influential, offering new perspectives on material strength and durability.

ACADEMIC CITATIONS

Prof. Tahiri’s work has been widely cited in academic conferences and journals. Notable publications include his assessment of structural, electronic, and mechanical properties of Re1‑xWxB2 diborides, presented at the International Conference on Energy and Green Computing in November 2023, and his first-principles calculations of new KXH3 (X = Mn, Fe) hydride compounds for hydrogen storage applications, presented at the World Energy Conference in December 2023. His research on Co2 x V x FeGe Full-Heusler Alloys was showcased at the Journee sur l’ingenierie des materiaux (JIM’23) in May 2023. These citations underscore the significance of his contributions to the scientific community.

LEGACY AND FUTURE CONTRIBUTIONS

Looking ahead, Prof. Abdellah Tahiri aims to continue his pioneering work in molecular dynamics and material sciences. His future contributions are expected to further enhance the understanding and application of nanocrystalline materials, particularly tungsten and its alloys. His legacy will be marked by his dedication to advancing scientific knowledge and his influence on the academic and research community, fostering innovation and excellence in the field of material science.

MOLECULAR DYNAMICS 

Prof. Tahiri's expertise in molecular dynamics has been central to his research, providing deep insights into the mechanical properties and structural behaviors of materials at the nanoscale. His use of molecular dynamics simulations to explore various mechanical tests and the effects of different parameters on material properties highlights the importance of this methodology in advancing material science. The keywords molecular dynamics encapsulate the core of his research approach, reflecting his commitment to utilizing cutting-edge techniques to uncover new knowledge and drive innovation in the field.

NOTABLE PUBLICATION