Tag: Quantum Simulations

Early Academic Pursuits

Dr. Bercioux’s academic journey began in Naples, Italy, where he earned his Laurea in Physics (summa cum laude) and Ph.D. from the Federico II University of Naples. His doctoral research, focused on spin-dependent transport in nanostructures, laid the groundwork for his later interest in quantum transport phenomena. Under the guidance of Professors V. Cataudella and V. M. Ramaglia, he developed strong foundations in low-dimensional physics and quantum electronics. His early education reflects exceptional academic performance, including a perfect score in his high school technical diploma.

Professional Endeavors

Over two decades, Dr. Bercioux has held progressively prestigious roles, beginning as a postdoctoral researcher in Germany (Regensburg, Freiburg, Berlin) and culminating in a tenured professorship at DIPC. He joined Ikerbasque in 2014, was promoted to Associate Professor in 2019, and now leads the Mesoscopic Electrons and Photons Systems (MEPS) group. His international collaborations include affiliations with the Université d’Aix-Marseille, Stanford University, and the University of Bordeaux. He’s also an editorial board member of Communication Physics and serves as advisor to the Phenikaa Institute in Vietnam.

Contributions and Research Focus

Dr. Bercioux’s research centers on graphene, spintronics, topological matter, non-Hermitian physics, and quantum simulation. He has contributed to the understanding of chiral edge states, photonic lattices, and pseudo-spin systems, and co-authored high-impact reviews in Review of Modern Physics and Reports on Progress in Physics. His group explores quantum effects in low-dimensional systems, bridging theory and experiment. With over 70 publications, including 18 letters in top-tier journals such as PRL, Nat. Mater., and Commun. Phys., he remains at the forefront of quantum condensed matter research.

Impact and Influence

With over 2,190 citations and an h-index of 23, Dr. Bercioux has significantly influenced the field of condensed matter physics. His work is regularly cited in top-tier journals, and he has delivered 70 invited talks across global institutions. He has organized more than 20 international schools and workshops, such as the renowned Capri Spring School series. He actively shapes scientific discourse as an editor, reviewer, and conference chair, with roles in high-profile review panels and editorial boards. His multidisciplinary collaborations enhance the global understanding of quantum transport and materials.

Academic Cites and Metrics

According to Web of Science (July 2025), Dr. Bercioux’s publication metrics include 70 peer-reviewed papers, over 2,190 citations, and an average of 31 citations per article. He has published in PRL, Nature Nanotech, Nat. Mater., and Advanced Quantum Technology, highlighting the quality and relevance of his work. He’s authored three reviews, three News & Views, and a lecture book for Springer, solidifying his standing as both a scholar and educator. His Research-ID and ORCID maintain up-to-date records of his contributions, evidencing his scientific integrity and productivity.

Research Skills

Dr. Bercioux excels in quantum transport theory, non-Hermitian physics, light-matter coupling, and spin-orbit photonics. His analytical prowess spans tight-binding models, topological classification, and synthetic lattices. He possesses deep expertise in multi-terminal quantum devices, photonic simulations, and Dirac systems. His interdisciplinary skills enable work on quantum materials for computation, superconductivity, and spin textures, contributing to quantum technology development. Skilled in project coordination, he has secured over €900,000 in competitive funding and mentored doctoral candidates, showcasing his ability to translate theoretical insight into impactful research outputs.

Teaching Experience

Dr. Bercioux has mentored 7 Ph.D. students and 11 undergraduates, guiding theses in mesoscopic physics, quantum transport, and topological systems. His teaching philosophy emphasizes foundational understanding and research readiness, often combining coursework with hands-on research. He’s organized and lectured at 18+ international physics schools, including the Capri Spring School, and hosted workshops on quantum materials. As a Privatdozent at Freiburg and later ASN-certified associate professor in Italy, his academic credentials enable him to teach across European institutions, enriching the physics curriculum with cutting-edge topics.

Awards and Honors

Dr. Bercioux has received several prestigious awards, including the Ikerbasque Research Fellowship, the ASN Italian National Qualification, and the Aix-Marseille Excellence Fellowship. He has earned multiple PhD grants, DFG and MINECO project funds, and international workshop sponsorships, reflecting trust from academic funding bodies across Europe and Asia. Recognized for scientific leadership, he serves on expert review panels for NWO, ESF, Romanian Research Council, and others. His work has also attracted support from the Basque Government, positioning him as a key figure in European quantum research.

Legacy and Future Contributions

Dr. Bercioux’s enduring legacy lies in his ability to bridge fundamental theory and real-world applications in quantum technologies. As a mentor, organizer, and collaborator, he is shaping the future of quantum simulations, non-Hermitian systems, and low-dimensional materials. Through his continued involvement in strategic projects like IKUR—Quantum and photonic simulators, he fosters innovation at the intersection of light and matter. His ongoing efforts in science diplomacy, editorial duties, and workshop leadership ensure that his influence will extend across generations, advancing both knowledge and mentorship in quantum physics.

Publications Top Notes

Colloquium: Synthetic quantum matter in nonstandard geometries

Authors: T. Grass, D. Bercioux, U. Bhattacharya, M. Lewenstein, H.-S. Nguyen, …
Journal: Reviews of Modern Physics 97 (1), 011001
Year: 2025

Wannier center spectroscopy to identify boundary-obstructed topological insulators

Authors: R.A.M. Ligthart, M.A.J. Herrera, A.C.H. Visser, A. Vlasblom, D. Bercioux, I. Swart
Journal: Physical Review Research 7 (1), 012076
Year: 2025

Correction to Topological Properties of a Non-Hermitian Quasi-1D Chain with a Flat Band

Authors: C. Martínez-Strasser, M.A.J. Herrera, A. García-Etxarri, G. Palumbo, F.K. Kunst, D. Bercioux
Journal: Advanced Quantum Technologies 8 (3)
Year: 2025

Chiral spin channels in curved graphene pn junctions

Authors: D. Bercioux, D. Frustaglia, A. De Martino
Journal: Physical Review B 108 (11), 115140
Year: 2023

Implementation and characterization of the dice lattice in the electron quantum simulator

Authors: C. Tassi, D. Bercioux
Journal: Advanced Physics Research 3 (9), 2400038
Year: 2024

Arunima Singh | Computational Methods | Best Researcher Award

Published on 18/06/202518/06/2025 by High Energy Physics

Prof. Arunima Singh | Computational Methods | Best Researcher Award

Assistant Professor at Arizona State University | United States

Dr. Arunima K. Singh is an Assistant Professor in the Department of Physics at Arizona State University (ASU) and a graduate faculty member in Materials Science and Engineering. Her research bridges computational materials science, applied physics, and machine learning, focusing on discovering novel materials for energy and electronic applications. She holds a Ph.D. from Cornell University and has conducted postdoctoral research at both NIST and Lawrence Berkeley National Lab. With over 57 publications, her work is highly regarded in the scientific community, earning prestigious awards, editorial roles, and invitations to speak globally on advanced materials research.

Profile

🎓 Early Academic Pursuits

Dr. Singh’s academic journey began with a B.Tech. (Honors) in Metallurgical and Materials Engineering from IIT Kharagpur, where she earned multiple academic awards and graduated with a departmental silver medal. She pursued graduate studies at Cornell University, receiving both M.S. and Ph.D. degrees in Materials Science and Engineering, with a minor in Applied Physics. Under the guidance of Prof. Richard G. Hennig, her doctoral work focused on theoretical materials design. Her education was supported by prestigious fellowships including the McMullen Fellowship and Dow Chemical Fellowship, laying a strong foundation for her future research career.

💼 Professional Endeavors

Dr. Singh’s professional experience spans national labs and academia. Following her Ph.D., she held postdoctoral appointments at the National Institute of Standards and Technology (NIST) and Lawrence Berkeley National Lab (LBNL), collaborating with leaders like Dr. Francesca Tavazza and Prof. Kristin Persson. Since 2018, she has been a faculty member at ASU, where she also contributes as a graduate mentor and research leader. Beyond teaching and research, she serves on editorial boards, national committees, and plays an active role in shaping research programs in the DOE Energy Frontier Research Center and TMS divisions.

🔬 Contributions and Research Focus

Dr. Singh specializes in computational materials discovery, leveraging density functional theory (DFT), GW-BSE methods, and machine learning to uncover materials for photocatalysis, solar energy, and 2D electronics. She has developed high-throughput workflows like pyGWBSE, enabling scalable simulations for optoelectronic properties. Her notable contributions include predictive models for nanoscroll formation, ultra-wide band gap semiconductors, and surface film protectiveness. She is a pioneer in integrating AI techniques with first-principles simulations, pushing the boundaries of how materials are discovered and optimized for real-world applications, with her work often featured in high-impact journals like npj Computational Materials and Advanced Functional Materials.

🌍 Impact and Influence

With over 4,300 citations, an h-index of 25, and continuous recognition in global venues, Dr. Singh’s influence is widespread. Her research has made foundational contributions to photocatalytic energy materials, grain boundary physics, and 2D nanomaterials. She has mentored students who have gone on to win prestigious poster and research awards, reflecting her impact as an educator and scientist. Invited to give keynote speeches and colloquia across institutions, from Caltech to international webinars, she is recognized as a thought leader in her field. She plays a key role in shaping policy and research strategy through MaRDA, DOE, and TMS platforms.

📊 Academic Cites

Dr. Singh’s work has been published in top-tier journals like npj 2D Materials & Applications, Nano Letters, and Annual Review of Condensed Matter Physics. Her publications are frequently cited, reflecting both depth and breadth of research impact across fields including computational materials science, nanotechnology, and machine learning in physics. Her most cited works address CO₂ reduction photocatalysts, vibrational EELS theory, and strain-induced nanoscrolls. As of March 2025, her Google Scholar profile records 4,396 citations, a 25 h-index, and 35 i10-index, a clear testament to the lasting relevance and utility of her contributions in cutting-edge research.

🧪 Research Skills

Dr. Singh brings expertise in first-principles simulations, high-throughput computing, and machine learning for materials design. She has built custom computational workflows like pyGWBSE and developed data-driven algorithms for stability and performance prediction. Her skillset includes GW-BSE optical simulations, phonon and defect state analysis, and interface science. She collaborates with both theory and experiment teams, enhancing the real-world applicability of her computational models. Proficient in Python, VASP, Quantum ESPRESSO, and emerging AI frameworks, her skills position her at the frontier of materials informatics, enabling novel discoveries in photocatalysis, electronics, and energy storage.

👩‍🏫 Teaching Experience

As an Assistant Professor at ASU, Dr. Singh has taught and mentored students in Physics and Materials Science, often integrating cutting-edge research topics into her coursework. Her mentorship has led to student-led publications, poster awards, and graduate research accolades. She actively supervises Ph.D. students, guiding them through interdisciplinary research spanning condensed matter physics, AI in materials, and 2D materials design. Beyond classroom teaching, she regularly delivers technical workshops, participates in graduate admissions, and contributes to curriculum development. Her commitment to fostering the next generation of scientists is evident in her consistent student-centered approach.

🏆 Awards and Honors

Dr. Singh has earned numerous national and institutional accolades, including the 2023 DOE Early Career Research Award, the 2024 TMS Young Leaders Professional Development Award, and several graduate fellowships from Cornell and Dow Chemical. She has been recognized for her contributions to women in applied physics, being featured in special issues and highlighted by AIP. Her students have also received competitive honors, reflecting her impact as a mentor. These awards underscore her leadership, innovation, and dedication to excellence in research and education, solidifying her status as a standout researcher in materials physics and computational science.

🔮 Legacy and Future Contributions

Dr. Singh is on a trajectory to become a defining voice in AI-enabled materials design and computational physics. Her legacy will likely include tools and frameworks that democratize high-performance computing for materials discovery. As she continues to shape research agendas at DOE centers and through editorial influence, her work will foster sustainable energy solutions, new semiconductor technologies, and broader STEM participation. With a proven record of mentoring, publishing, and innovating, Dr. Singh is building a future where data, physics, and computation converge to revolutionize how materials power the world.

Top Noted Publications

Many-body physics and machine learning enabled discovery of promising solar materials

Authors: T. Biswas, A. Gupta, and A. K. Singh*
Journal: RSC Advances
Year: 2025

Predicting the structure and stability of oxide nanoscrolls from dichalcogenide precursors

Authors: A. Gupta, and A. K. Singh*
Journal: APL Materials
Year: 2025

Atomic-Resolution Mapping of Localized Phonon Modes at Grain Boundaries

Authors: B. Haas, T. M. Boland, C. Elsasser, A. K. Singh, K. March, J. Barthel, C. T. Koch, and P. Rez
Journal: Nano Letters
Year: 2023

Ab Initio-Based Metric for Predicting the Protectiveness of Surface Films in Aqueous Media

Authors: R. Gorelik, and A. K. Singh*
Journal: npj Materials Degradation
Year: 2023

pyGWBSE: A High Throughput Workflow Package for GW-BSE Calculations

Authors: T. Biswas, and A. K. Singh*
Journal: npj Computational Materials
Year: 2023

Zhaocang Meng | Computational Methods | Best Researcher Award

Published on 12/06/2025 by High Energy Physics

Assist. Prof. Dr. Zhaocang Meng | Computational Methods | Best Researcher Award

Institute of Modern Physics, Chinese Academy of Sciences | China

Dr. Zhaocang Meng is a materials physicist specializing in first-principles simulations, irradiation damage modeling, and additive manufacturing of advanced materials. He earned his Ph.D. in Science through a joint program between the Institute of Modern Physics, Chinese Academy of Sciences (CAS) and Lanzhou University. His research spans the atomic-scale behavior of defects, mechanical property evaluation, and high-throughput screening for material optimization. Currently based at the Institute of Modern Physics, CAS, he is an integral contributor to strategic projects funded by both national and provincial Chinese foundations.

Profile

🎓 Early Academic Pursuits

Dr. Meng began his academic journey at Northwest Normal University, majoring in Physics and Electronic Engineering, where he laid the groundwork in material science and theoretical physics. He continued his master’s studies at the Institute of Modern Physics, CAS, focusing on radiation effects and material behavior. His intellectual curiosity and growing expertise led to a Ph.D. (2018–2021) in a joint doctoral program between CAS and Lanzhou University, where he honed his skills in density functional theory (DFT) and multi-scale simulations, preparing him for a robust career in theoretical and computational materials science.

💼 Professional Endeavors

Since July 2021, Dr. Meng has served as a researcher at the Institute of Modern Physics, Chinese Academy of Sciences, contributing to major national research initiatives, including the CAS Strategic Priority Program. His role encompasses both theoretical modeling and applied computation for nuclear-grade materials, ceramics, and metallic systems. He is actively involved in Grain Boundary Segregation Engineering for SiC and BeO, and supports the development of neural network potentials. His practical contributions extend to thermophotovoltaic energy systems and irradiation-resilient structural materials, demonstrating a bridge between computational insight and real-world application.

🔬 Contributions and Research Focus

Dr. Meng’s primary contributions lie in the atomistic modeling of radiation-induced defects, grain boundary behavior, and mechanical performance of ceramics and metals. His first-principles investigations in materials like Ti₃AlC₂, BeO, SiC, and Be₁₂Ti have revealed novel insights into defect–impurity interactions, hydrogen/helium diffusion, and segregation phenomena under extreme environments. He has also made impactful strides in the development of neural network potentials for materials like SiC, allowing large-scale simulations with quantum-level accuracy. His work directly supports the advancement of materials for nuclear reactors, space missions, and extreme-condition engineering.

🌍 Impact and Influence

Dr. Meng’s work has influenced fields such as nuclear materials, condensed matter theory, and computational materials science. His articles in high-impact journals like Physical Chemistry Chemical Physics, Journal of Nuclear Materials, and RSC Advances have become key references in radiation material modeling. His collaborations across diverse domains, from hydrogen embrittlement to deep potential learning for FCC copper, highlight his versatility. The adoption of his findings in defect prediction and grain boundary design has practical implications for materials used in reactors and space technology, positioning him as a rising figure in next-generation material research.

📚 Academic Cites

With a growing body of 14+ peer-reviewed publications, Dr. Meng’s research outputs have earned significant citations in domains like irradiation defect dynamics, machine-learned interatomic potentials, and grain boundary engineering. His work on Ti₃AlC₂ and Be₁₂Ti systems has been cited for its pioneering insights into defect clusters and transmutation effects, while his 2023 papers on SiC doping and neural network-based modeling have gained traction among materials engineers and computational physicists. His interdisciplinary footprint, combining physics, chemistry, and mechanical engineering, enhances his recognition across both academic and applied research networks.

🛠️ Research Skills

Dr. Meng demonstrates mastery in first-principles methods (DFT), molecular dynamics, machine learning potentials, and multi-scale simulation frameworks. His computational toolkit includes VASP, Quantum ESPRESSO, LAMMPS, and deep learning platforms like DeePMD-kit. He excels in automated high-throughput screening, grain boundary structure prediction, and radiation damage modeling. His ability to link atomic-level processes to macroscopic properties allows him to tackle engineering problems with atomic precision. He is adept at designing simulation protocols that align with experimental validations, ensuring a feedback loop between theory and practice a critical skill in today’s data-driven research environment.

👨‍🏫 Teaching Experience

While primarily a researcher, Dr. Meng has informally mentored junior scientists and graduate students during his tenure at the Institute of Modern Physics. He has contributed to internal training modules and simulation workshops focusing on first-principles methods and materials modeling software. As his academic journey matures, he is well-positioned to engage in formal teaching or curriculum development, especially in computational material science, AI-driven simulations, and solid-state physics. His clarity in technical writing and collaborative style suggest strong potential as a future university lecturer or postgraduate supervisor.

🏅 Awards and Honors

Although specific awards are not mentioned, Dr. Meng’s selection for national strategic research programs (e.g., CAS Grant No. XDA0410000) and provincial funding initiatives like Guangdong Basic Research Foundation reflect institutional recognition of his capabilities. His consistent publication record in top-tier international journals underscores his scientific credibility. Being chosen to lead studies involving Grain Boundary Engineering and deep learning potentials in cutting-edge materials confirms his reputation among peers and senior collaborators. With this trajectory, formal honors such as Young Scientist Awards or Outstanding Researcher Fellowships are highly likely in the near future.

🔮 Legacy and Future Contributions

Dr. Zhaocang Meng is poised to leave a lasting legacy in predictive materials design. His work in irradiation resistance, grain boundary tailoring, and AI-driven material exploration sets a solid foundation for next-gen energy systems, including fusion reactors, radioisotope thermoelectric generators, and space propulsion materials. Future contributions may include cross-disciplinary collaboration with AI scientists, sustainable materials discovery, and experimental validation partnerships. His potential to transition from a leading researcher to a thought leader and educator is evident. Dr. Meng represents a new era of materials scientists who bridge theory, computation, and practical innovation.

Top Noted Publications

Segregation and aggregation behavior of impurity atoms at grain boundaries of BeO: A first-principles study

Authors: Xuejie Wang, Teng Shen, Canglong Wang, Kai He, Zhaocang Meng*, et al.
Journal: Journal of Nuclear Materials
Year: 2025

Screening and manipulation by segregation of dopants in grain boundary of Silicon carbide: First-principles calculations

Authors: Z.C. Meng, C.L. Wang, Y.L. Wang, et al.
Journal: Ceramics International
Year: 2023

First-principles investigations of oxygen interaction with hydrogen/helium/vacancy irradiation defects in Ti₃AlC₂

Authors: Zhaocang Meng, Canglong Wang, Jitao Liu, Yinlong Wang, Xiaolu Zhu, Lei Yang, Liang Huang
Journal: Physical Chemistry Chemical Physics
Year: 2021

New insight into the interaction between divacancy and H/He impurity in Ti₃AlC₂ by first-principles studies

Authors: Zhaocang Meng, Canglong Wang, Jitao Liu, Yinlong Wang, Xiaolu Zhu, Lei Yang, Liang Huang
Journal: Physical Chemistry Chemical Physics
Year: 2020

Deep potential for a face-centered cubic Cu system at finite temperatures

Authors: Y.Z. Du, Z.C. Meng, Q. Yan, et al.
Journal: Physical Chemistry Chemical Physics
Year: 2022

Mohammed A. Al-Seady | Computational Methods | Best Researcher Award

Published on 09/06/2025 by High Energy Physics

Dr. Mohammed A. Al-Seady | Computational Methods | Best Researcher Award

PhD Student at University of Szeged/College of Science and Informatics | Hungary

Mohammed A. Al-Seady is a passionate and emerging materials scientist and computational physicist from Iraq, currently pursuing his PhD in Physics at the University of Szeged, Hungary. He serves as a researcher at the Center for Environmental Research and Studies, University of Babylon. With a Master’s degree in Molecular Sciences focusing on graphene-based materials, Al-Seady is deeply committed to advanced research in two-dimensional nanomaterials, renewable energy applications, and environmental remediation. He has authored 16 peer-reviewed articles, demonstrating his dedication to addressing critical scientific and global sustainability challenges through computational modeling and simulation techniques.

Profile

🎓 Early Academic Pursuits

Mohammed A. Al-Seady began his academic journey at the University of Babylon, where he earned his B.Sc. and M.Sc. degrees in Physics in 2015. His early fascination with nanostructures and materials science, particularly graphene, inspired him to specialize in Molecular Sciences. His academic performance and enthusiasm for scientific inquiry distinguished him early, earning him opportunities to work closely with faculty on graphene synthesis, material characterization, and fundamental physics modeling. These formative years laid a strong theoretical and experimental foundation for his future contributions in nanotechnology and computational materials physics.

💼 Professional Endeavors

Professionally, Al-Seady has held the position of Researcher at the Center for Environmental Research and Studies, University of Babylon, contributing to key environmental technology projects. Simultaneously, he is advancing his doctoral studies in Physics at the University of Szeged in Hungary. His professional path reflects a commitment to international academic collaboration, research excellence, and scientific development across both Iraq and Europe. By balancing his roles in academic research and higher education, he is establishing himself as a versatile scientist working on the intersection of theoretical physics, materials engineering, and green technology innovation.

🔬 Contributions and Research Focus

Mohammed’s research centers on two-dimensional (2D) materials such as graphene and hexagonal boron nitride (h-BN), with applied work in photovoltaics, ionic batteries, dye-sensitized solar cells (DSSCs), and gas adsorption. His work uses computational modeling tools like Gaussian09, Quantum ESPRESSO, and Materials Studio to simulate and optimize the performance of nanostructured materials. By focusing on environmental and energy applications, he contributes solutions to pollution control, energy storage, and solar energy harvesting, creating a bridge between theoretical studies and real-world environmental impact.

🌍 Impact and Influence

With 16 peer-reviewed publications, Mohammed A. Al-Seady’s research is gaining traction in the fields of computational nanomaterials, sustainable energy, and environmental technology. His interdisciplinary work helps shape the scientific discourse on the use of 2D materials in renewable energy and remediation systems. His involvement in both local research institutions and European academic networks demonstrates his ability to act as a scientific connector. Through his publications and collaborations, he is building an international research footprint and influencing future studies on green nanotechnology and computational simulations.

📚 Academic Citations

Al-Seady’s publications are indexed on Scopus and ResearchGate, reflecting a growing citation count and peer engagement. His Scopus author ID (57223213775) shows his inclusion in global citation networks, ensuring the visibility of his contributions to the academic community. Though still in the early stages of his research career, the consistent quality and relevance of his work are leading to increased citations in journals focusing on nanomaterials, computational physics, and clean energy. His scholarship is steadily building a reputation for rigor and applicability.

🧠 Research Skills

Mohammed has developed a robust technical skill set essential for advanced materials research. His proficiency in Python and C programming supports his work in numerical modeling and simulations, while tools like Quantum ESPRESSO and Gaussian09 enable him to perform high-accuracy density functional theory (DFT) calculations. His expertise extends to scientific writing, data interpretation, and computational analysis, making him an asset in both independent and collaborative projects. These skills allow him to design, model, and optimize novel nanomaterials for a wide range of energy and environmental applications.

👨‍🏫 Teaching Experience

While his profile emphasizes research, Mohammed has contributed to educational activities at the University of Babylon, supporting physics coursework and helping students understand quantum mechanics, computational modeling, and material science concepts. He has supervised undergraduate lab sessions and provided technical mentoring to research interns working on nanotechnology-related projects. His ability to translate complex scientific ideas into accessible educational content highlights his strength as an emerging educator. As he progresses in his career, his teaching contributions are expected to expand alongside his research output.

🔮 Legacy and Future Contributions

Mohammed A. Al-Seady is on a promising trajectory toward becoming a leading figure in computational materials science. His ongoing work aims to push the boundaries of 2D material applications for clean energy, sustainability, and pollution mitigation. With plans to broaden his research collaborations, mentor the next generation of scientists, and contribute to global scientific innovation, Mohammed’s legacy will likely include transformative contributions to green nanotechnology. As his career matures, he is expected to play a pivotal role in shaping scientific solutions for environmental and energy crises worldwide.

Top Noted Publications

Improved light harvesting with graphene/boron nitride nano-heteroislands: a high-efficiency photosensitizer design

Authors: Mohammed A. Al-Seady, Hayder M. Abduljalil, Hussein Hakim Abed, Mudar A. Abdullsatar, Rajaa K. Mohammad, Saif M. Hassan, Osamah J. Al-sareji, Mousumi Upadhyay Kahaly
Journal: Structural Chemistry
Year: 2024

Ethanol properties effects on its reaction with Mo-doped SnO₂ clusters: A gas sensor model

Authors: Mudar Ahmed Abdulsattar, Rashid Hashim Jabbar, Mohammed A. Al-Seady
Journal: Results in Surfaces and Interfaces
Year: 2024

Investigation of Nitrogen Dioxide Gas Sensing Characteristics in Boron Nitride and Aluminum Nitride Nanoribbons: A First Principles Study

Authors: Mohammed A. Al-Seady
Journal: Library Progress International
Year: 2024

Temperature and humidity effects on the acetone gas sensing of pristine and Pd-doped WO₃ clusters: A transition state theory study

Authors: Mudar Ahmed Abdulsattar, Hayder M. Abduljalil, Hussein Hakim Abed, Mohammed A. Al‑Seady
Journal: Journal of Molecular Modeling
Year: 2024

Unveiling the potential of graphene and S-doped graphene nanostructures for toxic gas sensing and solar sensitizer cell devices: insights from DFT calculations

Authors: S.A.A. Alsaati, Rabab Saadoon Abdoon, Eman Hamid Hussein, Hayder M. Abduljalil, Rajaa K. Mohammad, Mohammed A. Al-Seady, Ansaf N. Jasim, Noor Al-Huda Saleh, Lynet Allan
Journal: Journal of Molecular Modeling
Year: 2024

Vivek Kumar Jain | Computational Methods | Best Researcher Award

Published on 06/06/202506/06/2025 by High Energy Physics

Assoc. Prof. Dr. Vivek Kumar Jain | Computational Methods | Best Researcher Award

Associate Professor at Career Point University Kota | India

Dr. Vivek Kumar Jain is an accomplished Associate Professor of Physics at the School of Basic and Applied Sciences, Career Point University, Kota, Rajasthan. With a Ph.D. from Mohanlal Sukhadia University, he specializes in electronic structure, magnetic properties, and material science. He actively participates in academic committees including IQAC, NAAC, and IPR Cell. Dr. Jain’s academic journey reflects dedication to both teaching and research, contributing significantly to physics education and innovative materials research.

Profile

📚 Early Academic Pursuits

Dr. Jain’s academic foundation was laid in Rajasthan, completing his B.Sc. and M.Sc. in Physics from Dayanand Saraswati University, Ajmer. He earned his Ph.D. in 2018 focusing on the electronic and magnetic properties of intermetallic alloys. Alongside physics, he gained certifications in Information Technology (RSCIT) and a Diploma in IT, showcasing a versatile skill set. His early accolades in science and cultural competitions highlight a strong academic and extracurricular background from school through college.

💼 Professional Endeavors

Dr. Jain has over 15 years of teaching experience, beginning as an assistant professor at premier institutes like Poornima College of Engineering and Swami Keshwanand Institute. He currently serves as an Associate Professor at Career Point University since 2022. Throughout his career, he has held roles such as admission counselor, examination coordinator, and committee member for NAAC and BOS, reflecting his deep engagement in academic governance and student mentoring.

🔬 Contributions and Research Focus

His research primarily focuses on the first-principles computational studies of Heusler alloys and spintronic materials, investigating their structural, magnetic, elastic, and optical properties. Dr. Jain has authored numerous publications in prestigious journals like Journal of Electronic Materials and Journal of Superconductivity and Novel Magnetism. He has also contributed to studies on nanomaterials and electronic devices, further enriching materials science research.

🌟 Impact and Influence

Dr. Jain’s work has made significant strides in advancing the understanding of spin gapless semiconductors and half-metallic materials vital for spintronics and electronic applications. His research outputs have influenced both theoretical frameworks and experimental approaches in the field. Additionally, his active participation in patent publications demonstrates his commitment to applied sciences and innovation, bridging academic research with practical technologies.

📈 Academic Cites

With numerous publications in renowned international journals by publishers such as Springer and Elsevier, Dr. Jain’s research has garnered wide academic recognition. His collaborative work with experts and students has resulted in over 20 impactful journal papers and several conference proceedings. This body of work has contributed to the scientific community’s knowledge on electronic materials and inspired ongoing research in magnetism and material science.

🛠️ Research Skills

Dr. Jain excels in first-principles calculations, density functional theory (DFT), and computational material science. His expertise includes electronic structure analysis, magnetic property evaluation, and optical behavior studies of intermetallic and Heusler alloys. Complementing his theoretical skills, he is proficient in academic writing, data analysis, and research supervision, mentoring Ph.D. scholars in cutting-edge materials research.

👩‍🏫 Teaching Experience

With over 15 years as a dedicated physics educator, Dr. Jain has taught undergraduate and postgraduate students across multiple institutions. His roles span laboratory coordination, admission counseling, and academic mentorship, fostering student engagement in science. He emphasizes a practical and research-oriented approach to teaching, integrating his research insights into the curriculum to enhance learning outcomes in material physics and computational methods.

🏆 Awards and Honors

Dr. Jain has earned multiple accolades from early schooling days, including first positions in science and essay competitions at district and college levels. He was awarded the prestigious UGC Basic Science Research Fellowship (BSR), reflecting his academic excellence. His recognition spans debate competitions and research fellowships, underpinning a well-rounded profile of scholarly achievements and extracurricular distinction.

🔮 Legacy and Future Contributions

Dr. Vivek Kumar Jain continues to impact the scientific community through cutting-edge research, academic leadership, and innovative teaching. His future plans include expanding work on spintronic devices, nanomaterials applications, and fostering interdisciplinary collaborations. With ongoing patents and book publications, he is poised to contribute significantly to next-generation materials science and physics education, inspiring future researchers and students.

Top Noted Publications

First principles investigations of Fe₂CrSi Heusler alloys by substitution of Co at Fe site
Authors: Rakesh Jain, N. Lakshmi, Vivek Kumar Jain, Aarti R. Chandra
Journal: AIP Conference Proceedings
Year: 2018
Study of the electronic structure properties in Co₂NbIn/Sn Heusler alloys
Authors: Aarti R. Chandra, Vishal Jain, N. Lakshmi, Rakesh Jain, Vivek Kumar Jain
Journal: AIP Conference Proceedings
Year: 2018
Structural, Electronic and Optical Properties of ZnO material using first principle calculation
Authors: Jaiveer Singh, Vivek Kumar Jain
Journal: Journal of Polymer and Composites
Year: 2023
Effects of channel length and gate dielectric material on electrical properties of an IGZO TFT
Authors: Archana Jain, Vivek Kumar Jain, Lalit Kumar Lata, Abhinandan Jain
Journal: Materials Today: Proceedings
Year: 2022
Effect of temperature and Co-addition on phase stability, magnetic and electronic properties of Fe₂₋ₓCoₓMnAl quaternary Heusler alloys for spintronics devices
Authors: Ashok Yadav, Vivek Kumar Jain, Vinesh Attatappa, N. Lakshmi, Arun Sharma, Sarvesh Kumar Pandey, Shikha Awasthi
Journal: Journal of Alloys and Compounds
Year: 2025

Xiang-Gui Li | Computational Methods | Best Researcher Award

Published on 23/04/2025 by High Energy Physics

Prof. Xiang-Gui Li | Computational Methods | Best Researcher Award

Chair Professor at Beijing Information Science and Technology University | China

Li Xiang-Gui is a distinguished academic and researcher in computational and applied physics, currently serving as a Chair Professor at the School of Applied Science, Beijing Information Science and Technology University. With over three decades of experience, he is known for his influential work in quantum physics, numerical analysis, and hydrodynamic simulation, underpinned by a deep mathematical foundation.

Profile

🎓 Early Academic Pursuits

Dr. Li began his academic journey with a B.S. and M.S. in Applied Mathematics from the Beijing Institute of Technology, graduating with distinction. His strong interest in mathematical modeling and physical systems led him to pursue a Ph.D. at the Chinese Academy of Engineering and Physics, specializing in Applied Physics and Computational Mathematics—a critical step that shaped his interdisciplinary approach to research.

🧑‍🔬 Professional Endeavors

Dr. Li’s career spans prestigious institutions and vital academic roles. From 1989 to 2004, he worked as a Lecturer and Associate Professor at the University of Petroleum, followed by his role as Associate Professor at Beijing Information Technology Institute. Since 2004, he has been with Beijing Information Science and Technology University, where he served as Professor, Dean, and now as Chair Professor, contributing to both academic development and institutional growth.

🔬 Contributions and Research Focus

Dr. Li’s research covers a broad spectrum including computational physics, quantum theory, numerical simulations, and hydrodynamics. His work often bridges theoretical modeling and real-world applications, notably in fields involving complex physical systems and energy research. His expertise in numerical analysis plays a vital role in solving high-dimensional, non-linear physical problems through computational approaches.

🌍 Impact and Influence

With a career deeply rooted in education, leadership, and advanced research, Dr. Li has influenced numerous students, academic programs, and scientific advancements. His work has applications in petroleum research, defense simulations, and quantum mechanics, impacting both academia and industry. His long tenure as a dean and academic leader illustrates his capability to shape research culture and foster innovation.

📚 Academic Cites and Recognition

Though specific citation metrics are not listed, Dr. Li’s national recognition, such as the Third Prize for Outstanding Research from the National Petroleum Corporation of China (1998), attests to the quality and societal impact of his research. His Ph.D. from a top-tier national research academy further adds to his credibility as a leading scientist in his field.

🧪 Research Skills

Dr. Li possesses deep expertise in computational modeling, quantum simulation, numerical methods and algorithms, and hydrodynamic code development. These advanced skills empower him to address multi-scale and multi-physics problems across both academic and applied research environments. By leveraging his strong foundation in mathematics, he effectively utilizes it as a powerful tool for scientific discovery, enabling precise simulation and analysis of complex physical systems.

👨‍🏫 Teaching Experience

Over his long academic career, Dr. Li has mentored numerous undergraduate, postgraduate, and doctoral students. His contributions as a professor and former dean reflect his dedication to education, curriculum development, and academic mentorship in the fields of applied mathematics and physics.

🏅 Awards and Honors

Dr. Li was awarded the Third Prize for Outstanding Research by the National Petroleum Corporation of China in 1998, a recognition of his exceptional research contributions with practical industrial value. This award marks him as a nationally recognized expert in simulation-based research.

🌟 Legacy and Future Contributions

As a Chair Professor and senior academic leader, Dr. Li is expected to continue shaping the future of computational physics and scientific education in China. With his deep foundation in theory and extensive experience, his legacy lies not only in his research output, but also in his institutional leadership and mentorship of the next generation of scientists.

Publications Top Notes

The Energy-Diminishing Weak Galerkin Finite Element Method for the Computation of Ground State and Excited States in Bose-Einstein Condensates

Authors: L. Yang, X. Li (Xianggui Li), W. Yan, R. Zhang
Journal: Journal of Computational Physics
Year: 2025

High-Order Numerical Methods with Mass and Energy Conservation for Spin–Orbit-Coupled Bose–Einstein Condensates

Authors: Xiang-Gui Li, Shu-Cun Li
Journal: International Journal of Computer Mathematics
Year: 2021

High-Order Conservative Schemes for the Nonlinear Dirac Equation

Authors: Shu-Cun Li, Xiang-Gui Li
Journal: International Journal of Computer Mathematics
Year: 2020

Self-Organization of Ultra-Thin Uranium Film

Authors: X. Li, S. Li, M. Li, M. Zhou, F. Zheng, P. Zhang
Journal: Physics Letters A: General, Atomic and Solid State Physics
Year: 2019

High-Order Compact Methods for the Nonlinear Dirac Equation

Authors: S.-C. Li, X.-G. Li
Journal: Computational and Applied Mathematics
Year: 2018

Sathish Panneer Selvam | Theoretical Advances | Best Scholar Award

Published on 22/04/2025 by High Energy Physics

Dr. Sathish Panneer Selvam | Theoretical Advances | Best Scholar Award

Assistant Professor at Gachon university | South Korea

Dr. Sathish Panneer Selvam is a dynamic Assistant Professor at Gachon University, South Korea, specializing in electrochemical biosensors, nanomaterials, and density functional theory (DFT). With a strong foundation in experimental chemistry and computational modeling, Dr. Selvam’s interdisciplinary research bridges the gap between biomedical diagnostics and renewable energy catalysis, contributing significantly to next-generation sensor technologies.

Profile

🎓 Early Academic Pursuits

Dr. Selvam began his academic journey with a Master’s degree in Electrochemical Sensing and Water Splitting under Prof. Kyusik Yun, where he focused on DNA-based nanomaterials and self-assembled sensors. He pursued his PhD (2020–2024) under Prof. Sungbo Cho, contributing to sensor development for disease diagnostics and reaction mechanism analysis via DFT. This formative period laid the groundwork for his future breakthroughs in smart diagnostics.

💼 Professional Endeavors

Starting as a Quality Control Executive at Biocon Biopharmaceutical Ltd., Dr. Selvam transitioned seamlessly into academia. His current role as an Assistant Professor (2024–2025) at Gachon University involves leading advanced biosensing projects, such as cancer diagnostics, enzyme activity detection, and nanocomposite development. His hands-on expertise spans fabrication, characterization, and computational modeling.

🔬 Contributions and Research Focus

Dr. Selvam’s research is distinguished by its interdisciplinary depth and real-world relevance. He has designed single-atom catalyst biosensors for detecting pancreatic and breast cancer. Additionally, he has explored molecularly imprinted polymers for biomarker detection and utilized DFT and molecular dynamics to simulate reaction pathways. His development of triboelectric nanogenerators for self-powered bacterial detection reflects his ability to address critical challenges in medical diagnostics, environmental monitoring, and energy applications.

🌍 Impact and Influence

Dr. Selvam has authored 16+ peer-reviewed publications, many in high-impact journals such as Chemical Engineering Journal, Small Methods, and Biosensors and Bioelectronics, with impact factors ranging from 8 to 23. His contributions to cancer biosensing, H2 evolution, and COVID-19 detection have attracted international collaborations with researchers from UK, France, and India, solidifying his global influence.

📊 Academic Cites & Recognition

Dr. Selvam’s work is increasingly cited by peers in the fields of biosensors, nanotechnology, and theoretical chemistry. With several publications already gaining traction in the academic community, he is on track for significant citation growth and thought leadership in applied quantum chemistry and nanomedicine.

🧪 Research Skills

Dr. Selvam demonstrates a robust technical skill set that seamlessly bridges experimental techniques with computational modeling. He excels in electrochemical characterization using systems like Iviumstat, Biologics, and PARSTAT. His expertise in structural analysis includes SEM, TEM, XRD, EXAFS, and Raman spectroscopy. Additionally, he is proficient in High-Performance Liquid Chromatography (HPLC) and a variety of spectroscopic tools. On the theoretical side, he utilizes DFT simulations, molecular docking, and molecular dynamics, allowing for deep insights into complex reaction mechanisms.

🎓 Teaching Experience

As an Assistant Professor, Dr. Selvam is engaged in mentoring undergraduate and graduate students. He fosters a research-driven learning environment that encourages critical thinking, scientific writing, and interdisciplinary collaboration, essential for shaping future scientists.

🌟Patents

Dr. Selvam holds several patents, including the Chalcogenide Loaded Cobalt MOF for Patulin Mycotoxin Detection (KR Patent 10-2437215), an Electrochemical Biosensing Platform for Rheumatoid Arthritis Biomarker detection (KR Patent 10-2381031), and a Nanocomposite modified electrode for Etidronic acid detection (KR Patent 10-2475238), co-authored with Sungbo Cho and Kyusik Yun. These innovations demonstrate his expertise in biosensing, electrochemical platforms, and biomarker detection.

📘 Legacy and Future Contributions

Dr. Selvam has a strong portfolio of patents, a growing reputation in academic publishing, and a unique ability to synthesize experimental and computational insights. As a thought leader in smart biosensing and energy catalysis, his future contributions are expected to include the development of scalable diagnostic tools for global health, AI-integrated sensor platforms, and further exploration of quantum chemistry for bio-interfaces. His work promises significant advances in both healthcare and energy solutions.

Publications Top Notes

EXAFS and spectroscopic insights into Mn, Tc, and Re-doped phthalocyanines: A multifaceted DFT study of electronic and optical properties

Authors: Sathish Panneer Selvam, Zeeshan, Sungbo Cho
Journal: Surfaces and Interfaces
Year: 2025

Cerium single atom anchored silver selenide: A high-performance catalyst for hydrogen evolution reaction with ultra-low activation energy and enhanced stability

Authors: Sathish Panneer Selvam, Sungbo Cho
Journal: Surfaces and Interfaces
Year: 2024

Experimental insights and DFT analysis of metal-free DNA nanocatalyst with enhanced hydrogen evolution via phosphate-mediated proton acceptance

Authors: Sathish Panneer Selvam, Shanmugasundaram Kamalakannan, K. Rudharachari Maiyelvaganan, Muthuramalingam Prakash, Sivalingam Gopi, Hansa Mahajan, Kyusik Yun, Sungbo Cho
Journal: International Journal of Hydrogen Energy
Year: 2024

Highly Synergistic Co3+ and Pyridinic‐N‐Rich Bifunctional Electrocatalyst for Ultra‐Low Energy-Driven Effective Hydrogen Production and Urea Oxidation

Authors: Sathish Panneer Selvam, Sungbo Cho
Journal: Advanced Sustainable Systems
Year: 2022

Novel SeS2-loaded Co MOF with Au@PANI comprised electroanalytical molecularly imprinted polymer-based disposable sensor for patulin mycotoxin

Authors: Sathish Panneer Selvam
Journal: Biosensors and Bioelectronics
Year: 2021

Hoc Nguyen | Computational Methods | Best Researcher Award

Published on 29/03/2025 by High Energy Physics

Assoc. Prof. Dr. Hoc Nguyen | Computational Methods | Best Researcher Award

Senior Lecturer at Hanoi National University of Education | Vietnam

Nguyen Quang Hoc D, Assoc. Prof. PhD, is a distinguished academic and researcher in the field of Theoretical Physics. He currently holds the position of High-ranking Lecturer at the Department of Theoretical Physics, Faculty of Physics, at the Hanoi National University of Education, where he has contributed extensively to both teaching and research since 2009. His academic journey reflects a deep commitment to physics, spanning over decades of study and experience in solid-state physics, theoretical physics, and mechanical properties of materials.

Profile

Early Academic Pursuits 🎓

Nguyen Quang Hoc D embarked on his academic career with a solid foundation in solid-state physics, earning his Engineer degree from Hanoi University of Technology in 1982. His deep interest in theoretical physics led him to pursue advanced studies at the Hanoi National University of Education, where he completed his Master’s degree in Theoretical Physics in 1989 and later achieved his PhD in 1994, further honing his expertise in the field.

Professional Endeavors 💼

His professional career began in 1983 at the College of Teacher Training (now Haiphong University), where he served as a Lecturer and Head of the Physical Laboratory until 1994. Later, he joined the Institute of Nuclear Science and Technique, VINATOM in 1994, contributing as a Researcher. In 1997, he transitioned to the Department of Scientific Management, Faculty of Physics at Hanoi National University of Education, where he took on roles as an Expert and Principal Lecturer until he became an Associate Professor in 2009. Since 2016, he has remained in his current capacity as a High-ranking Lecturer at the university.

Contributions and Research Focus 🔬

Prof. Nguyen Quang Hoc D has focused much of his research on mechanical and thermodynamic properties of metals and interstitial alloys, particularly through the statistical moment method. His work has provided valuable insights into the transport properties of superconductors and how artificial nanostructures can influence these properties. His research has significant implications in materials science, particularly in understanding how nanostructures can improve the performance of superconductors in real-world applications.

Impact and Influence 🌍

With a career spanning more than three decades, Assoc. Prof. Nguyen Quang Hoc D has made lasting contributions to both academic research and teaching. His work on superconductors and nanostructure materials has advanced our understanding of the mechanical and thermodynamic properties of advanced materials. His findings have opened the door for further studies in nanotechnology and material science, positioning him as a leading figure in the development of advanced materials in the Vietnamese academic community.

Academic Citations 📚

Prof. Nguyen Quang Hoc D has earned recognition for his work, resulting in numerous academic citations and publications in international journals related to materials physics. His contributions to the field of theoretical physics have significantly impacted the understanding of interstitial alloys, superconductivity, and the behavior of metals under extreme conditions, making him a respected authority in his field.

Research Skills 🧠

Assoc. Prof. Nguyen Quang Hoc D possesses advanced research skills in statistical methods, materials characterization, and nanotechnology. His expertise includes the application of the statistical moment method to study the thermodynamic behavior of materials, allowing him to analyze and predict the mechanical properties of metals and alloys under various conditions. He has also worked on superconductivity, making contributions to transport properties and the influence of nanostructure pinning on type-II superconductors.

Teaching Experience 👨‍🏫

Assoc. Prof. Nguyen Quang Hoc D has a wealth of teaching experience, spanning over two decades at the Hanoi National University of Education. He has taught a range of undergraduate and graduate courses in theoretical physics and solid-state physics, providing students with foundational knowledge while also challenging them with cutting-edge concepts in the field. His role as a mentor and principal lecturer has helped shape the next generation of physicists and scientists in Vietnam.

Awards and Honors 🏅

Throughout his career, Assoc. Prof. Nguyen Quang Hoc D has been the recipient of various awards and honors in recognition of his contributions to the field of physics. His dedication to both research and teaching has earned him respect within the academic community, and he continues to inspire those around him with his innovative research and commitment to excellence.

Legacy and Future Contributions 🌱

As Assoc. Prof. Nguyen Quang Hoc D continues his work at Hanoi National University of Education, his legacy remains rooted in his innovative research, teaching dedication, and academic leadership. Moving forward, he is expected to continue influencing the field of material science, particularly in the realms of superconductivity and nanotechnology. His future contributions will undoubtedly lead to advancements in the understanding of metals, alloys, and superconductive materials, strengthening the scientific community in Vietnam and beyond.

Publications Top Notes

On the Melting of Crystal Under Compression: SMM Fundamental Theory and its Application to Laser Materials Processing

Authors: Nguyen Quang Hoc, Le Hong Viet
Journal: Transactions of the Indian Institute of Metals
Year: 2025

Theoretical predictions of thermodynamic properties, elastic deformation, HCP-FCC structural phase transition and melting of iron at high temperatures up to 18000 K and high pressures up to 4000 GPa

Authors: Nguyen Quang Hoc, Nguyen Duc Trung, Hua Xuan Dat, Le Thu Lam
Journal: Physics Letters A
Year: 2025

Correction: Thermodynamic properties of perovskite MgSiO3 with cubic structure under extreme conditions

Authors: Quang Hoc Nguyen, Nhi Quynh Ngo, Thi Mai Dao, Cong Vien Tran, Thi Thu Tra Lai, Thi Van Anh Le, Thi Thuy An Nguyen
Journal: The European Physical Journal B
Year: 2024

Thermodynamic properties of perovskite MgSiO3 with cubic structure under extreme conditions

Authors: Hoc Quang Nguyen, Nhi Quynh Ngo, Mai Thi Dao, Vien Cong Tran, Tra Thi Thu Lai, Anh Thi Van Le, An Thi Thuy Nguyen
Journal: The European Physical Journal B
Year: 2024

Study on Remelting of Crystal Under Extreme Conditions

Authors: Hoc Quang Nguyen, Huyen Thanh Thi Tran, Nhi Quynh Ngo, Mai Thi Dao, Phong Khac Nguyen
Journal: Transactions of the Indian Institute of Metals
Year: 2024

Ali Zaoui | Computational Methods | Computational Science Excellence Award

Published on 28/02/2025 by High Energy Physics

Prof. Ali Zaoui | Computational Methods | Computational Science Excellence Award

Djillali Liabes University of SIDI BELI ABBES | Algeria

Ali Zaoui is a Professor and Team Leader at the Physics Computational Materials Laboratory at the University of Sidi Bel Abbes, Algeria. With a distinguished career spanning several decades, he has made significant contributions to the field of computational materials science. Zaoui holds a PhD in Material Sciences and has taught in various capacities, progressing from General Physics to Nanotechnology at the University of Sidi Bel Abbes.

Profile

Early Academic Pursuits 🎓

Zaoui’s academic journey began with a B.Sc. in Physics from the University of Sidi Bel Abbes (1991-1996). He then pursued a M.Sc. in Solid State Physics (1998-2000), focusing on the electronic structure of BSb compounds using the FP-LAPW method. Zaoui continued his academic pursuit with a Ph.D. in Material Sciences (2000-2005), conducting groundbreaking research on TiCxN1−x, ZrxNb1−xC, and HfCxN1−x alloys through first-principles calculations. His early work established a foundation in ab-initio methods for studying the electronic structures of complex materials.

Professional Endeavors 🧑‍💼

Zaoui’s professional career includes roles as a Professor at the University of Sidi Bel Abbes, where he has been an influential faculty member since 2005. Additionally, he has held leadership roles, such as Team Leader and Director of various computational material science laboratories. His contributions extend beyond teaching, as he has also served in prominent positions such as Dean of the Faculty of Exact Sciences at the Djillali Liabes University and President of the Doctoral Formation Committee.

Contributions and Research Focus 🔬

Zaoui’s research focus spans a range of topics, with particular emphasis on computational physics, material science modeling, and condensed matter physics. His expertise lies in studying strongly correlated systems, magnetism, and superconductivity in atomic and condensed matter physics. His contributions in first-principles calculations have advanced the understanding of alloy properties, nanostructures, and electronic behaviors of various materials. Notable works include research on Hf3N4 and Zr3N4 compounds, as well as RE2Ni2Pb (R=Er, Ho), contributing to the advancement of material science through simulation and modeling techniques.

Impact and Influence 🌐

Zaoui’s impact in the field of computational material science is substantial, with significant influence in educating future generations of physicists. As a team leader, he has guided a range of research projects that continue to shape the field. His involvement in summer schools, conferences, and workshops on DFT, simulation methods, and materials modeling has contributed to international collaborations and the sharing of knowledge on an international scale. His research has shaped the academic landscape of materials science, particularly in Algeria and North Africa.

Academic Cites 📚

Zaoui’s academic works have gained significant recognition and have been cited in a wide array of material science journals. His research on Hf3N4 and Zr3N4 compounds, along with his contributions to optical properties of semiconductors and first-principles simulations, has been referenced widely in the scientific community. His work is highly regarded for its accuracy, innovation, and practical application in understanding the electronic structures of materials.

Research Skills 🧑‍🔬

Zaoui’s research is known for the depth of computational analysis and precision in applying first-principles calculations. He is highly skilled in using DFT, LDA+U methods, and ab-initio techniques to model complex material properties, from magnetism to superconductivity. His computational techniques allow for predictive modeling of material behaviors, an essential aspect in the development of new materials for various applications. Zaoui’s research is marked by his ability to bridge theory with practical outcomes, bringing computational insights into real-world scenarios.

Teaching Experience 📖

Zaoui has a rich and diverse teaching experience, spanning from general physics to specialized subjects like magnetism, thermodynamics, and nanotechnology. He has taught at both undergraduate and graduate levels, including at institutions like the Higher School of Computer Science of Sidi Bel Abbes. His teaching extends beyond the classroom, having led seminars, summer schools, and research conferences. His commitment to educating the next generation of physicists has made a lasting impact on the scientific community in Algeria.

Awards and Honors 🏆

While detailed awards are not listed in the provided information, Zaoui’s significant contributions to computational material science, his leadership in education, and his influential research undoubtedly position him for recognition in various academic circles. His leadership role in organizing scientific committees and overseeing doctoral training programs reflects his contribution to the academic excellence in material science.

Legacy and Future Contributions 🌱

Zaoui’s legacy is deeply rooted in his research, teaching, and leadership in computational materials science. His future contributions are expected to continue influencing the advancement of computational tools and material science innovations. With his focus on nanotechnology, superconductivity, and magnetism, Zaoui is well-positioned to make future breakthroughs in the understanding of next-generation materials. As his work continues to inspire the global research community, Zaoui’s legacy will likely shape the future of computational materials science and nanotechnology for many years to come.

Publications Top Notes

Impact of polymer binders on the aggregation modes of two-pieces CSH composites

Authors: J., Jia, Jiwei; A., Zaoui, Ali; W., Sekkal, Wassila
Journal: Cement and Concrete Research, Year: 2025

Molecular modeling of clay minerals: A thirty-year journey and future perspectives

Authors: A., Zhou, Annan; J., Du, Jiapei; A., Zaoui, Ali; W., Sekkal, Wassila; M.S., Sahimi, Muhammad Syamim
Journal: Coordination Chemistry Reviews, Year: 2025

Crystal structure and magnetic properties of lithium nitridoferrate: Density functional theory calculations

Authors: M.R., Aced, Mohammed Reda; N., Benayad, Nawel; F., Drief, F.; S., Kacimi, Salima; M., Djermouni, Mostefa
Journal: Journal of Magnetism and Magnetic Materials, Year: 2025

Exploring superconducting signatures in high-pressure hydride compounds: An electronic-structure analysis

Authors: C., Mohammed Krarroubi; N., Benayad, Nawel; F., Benosman, Fayssal; S., Kacimi, Salima; A., Zaoui, Ali
Journal: Physica C: Superconductivity and its Applications, Year: 2025

Influence of particle size distribution and normal pressure on railway ballast: A DEM approach

Authors: Z., Yan, Zhu; A., Zaoui, Ali; W., Sekkal, Wassila
Journal: High-speed Railway, Year: 2025

Discrete-Element Method Study of the Effect of Ballast Layer Depth on the Performance of Railway Ballast Bed

Authors: Z., Yan, Zhu; A., Zaoui, Ali; W., Sekkal, Wassila
Journal: International Journal of Geomechanics, Year: 2025

Xiong Zhang | Computational Particle Physics | Best Researcher Award

Published on 21/02/202521/02/2025 by High Energy Physics

Mr. Xiong Zhang | Computational Particle Physics | Best Researcher Award

Yan’an University | China

Xiong Zhang is a Lab Technician at the College of Physics and Electronic Information, Yan’an University. Born in Suide, Shaanxi, in September 1990, he has emerged as an innovative researcher in the field of electronic communications . Zhang is currently a PhD Candidate with a strong academic background and a focus on photocatalysis, MEMS systems, and smart technologies. His work spans research, teaching, and practical innovations, making him a significant contributor to both academia and industry.

Profile