Soumia Chqondi | Atomic Physics | Research Excellence Award

Published on by Applied Scientist

Research Excellence Award

Soumia Chqondi
Laboratory ISTM (Innovation in Sciences, Technologies, and Modeling), Department of Physics, Faculty of Science, Chouab Doukkali University, Morocco
Soumia Chqondi
Affiliation Laboratory ISTM, Department of Physics, Faculty of Science, Chouab Doukkali University
Country Morocco
Scopus ID 55566736600
Documents 5
Citations 1
h-index 1
Subject Area Atomic Physics
Event Applied Scientist Awards

Soumia Chqondi is a Moroccan academic researcher specializing in atomic physics, laser–matter interaction, numerical simulation, and quantum system dynamics. Her scholarly work primarily focuses on theoretical and computational investigations involving intense laser fields and photoionization processes in atomic systems. Through her affiliation with the Laboratory ISTM and the Department of Physics at Chouab Doukkali University, she has contributed to studies involving strong-field ionization, electron dynamics, and two-color laser configurations used in advanced photonics and quantum physics research.[1] Her academic activities further include scientific supervision, university-level teaching, and participation in international scientific conferences dedicated to atomic and computational physics.[2]

Abstract

Soumia Chqondi in the field of atomic physics and computational laser–matter interactions. Her research portfolio includes theoretical modeling, numerical simulations, and analysis of photoionization phenomena involving hydrogen, helium, and argon atoms exposed to intense laser environments. Her investigations have contributed to understanding electron dynamics under infrared and high-frequency laser fields using time-dependent quantum approaches and advanced computational methods.[3] The body of work presented through peer-reviewed journal publications, conference proceedings, and collaborative scientific initiatives demonstrates sustained engagement with modern theoretical physics and applied computational science.[4]

Keywords

Atomic Physics; Laser–Matter Interaction; Photoionization; Quantum Dynamics; Strong-Field Physics; Numerical Simulation; Two-Color Laser Fields; Computational Physics

Introduction

Modern atomic physics increasingly depends on numerical and theoretical methods to interpret the interaction between matter and ultra-intense laser fields. Research in this area contributes to developments in spectroscopy, photonics, quantum mechanics, and ultrafast physical processes. Soumia Chqondi has participated in this evolving scientific domain through studies involving the dynamics of atoms subjected to strong-field and two-color laser systems.[2] Her academic background includes doctoral research conducted jointly between Moroccan and French institutions, emphasizing complex quantum systems and high-frequency laser interactions. These research activities align with broader scientific objectives related to computational modeling and applied theoretical physics.[5]

Research Profile

Soumia Chqondi serves as an academic researcher and lecturer in atomic physics and computational modeling. Her work is associated with the Laboratory ISTM and includes collaboration with scientific laboratories focusing on advanced materials, laser interaction, and complex dynamical systems. Her educational background comprises doctoral and master’s training in theoretical physics, laser science, and nanophysics. The primary themes of her research include photoelectron angular distributions, ionization dynamics, numerical treatment of the time-dependent Schrödinger equation, and strong laser-field simulations.[1]

Research Contributions

Soumia Chqondi largely focus on the theoretical description and simulation of atomic ionization processes under strong laser conditions. Her research has examined argon and hydrogen photoionization under infrared and extreme ultraviolet laser combinations, particularly through two-color configurations that enable analysis of electron angular distributions and spectral properties.[2]

Publications

  • Numerical Simulation of Photoionization Processes of the Atomic Hydrogen by a Ti:Saphir Laser, International Journal of Photonics and Optical Technology, 2017.
  • Floquet Theory in Electron-Helium Scattering in an Nd-YAG Laser Field, Optical and Photonics Journal, 2013.

Research Impact

Soumia Chqondi demonstrates active participation in computational atomic physics and strong-field laser interaction studies. Her work contributes to scientific understanding related to ionization mechanisms, electron spectral analysis, and nonlinear atomic behavior in high-intensity electromagnetic environments.[3] The integration of numerical simulation techniques with theoretical quantum models supports applications in photonics, spectroscopy, and laser-assisted atomic processes.

Award Suitability

Soumia Chqondi demonstrate alignment with the objectives of the Applied Scientist Awards and the Research Excellence Award category. Her research contributions emphasize theoretical innovation, computational methodology, and scientific investigation within atomic and laser physics. Through peer-reviewed publications, scientific presentations, and educational engagement, she has contributed to advancing applied theoretical research in quantum and laser-driven systems.[5]

Conclusion

Soumia Chqondi has established a research profile centered on atomic physics, strong-field laser interaction, and computational quantum analysis. Her scholarly activities demonstrate continued engagement with theoretical and numerical approaches to photoionization and electron dynamics. Through academic teaching, conference participation, and scientific publication, she contributes to the broader scientific community focused on laser physics and computational modeling.[1] The body of work presented within this article reflects the criteria commonly associated with scholarly recognition in applied scientific research.

References

  1. Elsevier. (n.d.). Scopus author details: SOUMIA CHQONDI, Author ID 55566736600. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=55566736600
  2. Chqondi, S., Chaddou, S., & Makhoute, A. (2024). Photoelectron angular distributions for photoionization of argon by two-color fields. Modern Physics Letters A.
    https://www.worldscientific.com/doi/full/10.1142/S0217732324300052
  3. Chqondi, S., Chaddou, S., Laghdas, A., & Makhoute, A. (2025). Controlling the Ionization Dynamics of Argon Induced by Intense Laser Fields: From the Infrared Regime to the Two-Color Configuration. Atoms.
    https://doi.org/10.3390/atoms13070063
  4. Chaddou, S., Chqondi, S., Taoutioui, A., & Makhoute, A. (2019). Theoretical description of the two-color photoelectron spectra process of hydrogen. Turkish Journal of Physics.
    https://doi.org/10.3906/Fiz-1807-27
  5. M. Chqondi, S. Chqondi,. & Y. Akdim. (2024). A New Feedback Control for Exponential and Strong Stability of Semi-Linear Systems with General Decay Estimates.
    https://e-ndst.kiev.ua/v24n1/4(91).pdf

Xinhua Zhang | Quantum Computing | Innovative Research Award

Published on by Applied Scientist

Innovative Research Award

Xinhua Zhang
Changzhou Institute of Technology, China
Xinhua Zhang
Affiliation Changzhou Institute of Technology
Country China
Scopus ID 58098441300
Documents 8
Citations 55
h-index 4
Subject Area Quantum Computing
Event Applied Scientist Awards
ORCID 0000-0001-9737-0064

Xinhua Zhang of Changzhou Institute of Technology has contributed to interdisciplinary research involving quantum information processing, surface plasmon physics, and low-temperature plasma medical devices. His research activities integrate theoretical physics concepts with applied engineering approaches focused on sterilization, coagulation systems, and plasma-assisted biomedical technologies.[1] The academic profile associated with Zhang reflects ongoing contributions to translational scientific development through patents, indexed publications, and collaborative industrial innovation initiatives.[2]

Abstract

Xinhua Zhang is a researcher affiliated with Changzhou Institute of Technology whose work spans quantum information processing, surface plasmon physics, and low-temperature plasma biomedical engineering. His research profile combines theoretical foundations in physics with practical engineering applications focused on sterilization systems, wound healing technologies, and plasma-assisted coagulation devices.[1] Zhang has participated in multiple regional science and technology projects and has contributed to industry-oriented research collaborations involving portable plasma medical equipment and healthcare technology innovation.[3] His scholarly output includes indexed journal publications, patent development activities, and translational research initiatives designed to bridge laboratory science with industrial and medical implementation.[2]

Keywords

Quantum Computing, Quantum Information Processing, Surface Plasmons, Low-Temperature Plasma, Biomedical Engineering, Plasma Sterilization, Medical Device Innovation, Applied Physics, Coagulation Devices, Scientific Research

Introduction

Interdisciplinary research increasingly plays an important role in advancing modern scientific innovation, particularly within fields that combine theoretical science with practical technological applications. The integration of quantum physics concepts with biomedical engineering has generated new possibilities for medical instrumentation, sterilization systems, and therapeutic technologies.[4] Researchers contributing to these areas often engage in both academic scholarship and industrial translation activities designed to improve technological accessibility and clinical functionality.

Xinhua Zhang has developed a research trajectory focused on plasma-assisted biomedical systems and quantum-related scientific investigations. His doctoral training in physics included studies associated with surface plasmons and quantum state control, while subsequent professional activities expanded toward low-temperature plasma applications in medicine and healthcare engineering.[1] These activities illustrate the growing relationship between applied physics and medical device innovation within contemporary scientific research.

Research Profile

Xinhua Zhang completed doctoral studies in physics at the University of York, where the research emphasis included surface plasmon phenomena and methods for controlling quantum states.[1] His academic and professional activities later expanded into applied plasma technologies involving sterilization, coagulation systems, and portable biomedical devices. The interdisciplinary nature of his work reflects collaboration between physics, healthcare engineering, and translational industrial research.

Research participation has included multiple science and technology initiatives supported by provincial and regional innovation programs in China. These projects involve plasma sterilization systems, air plasma coagulation technologies, and portable healthcare devices intended for biomedical applications.[3] Zhang has additionally contributed to industrial collaborations associated with technology commercialization and engineering optimization activities.

  • Research specialization in quantum information processing and low-temperature plasma technologies.
  • Participation in regional science and technology innovation programs.
  • Development of plasma-assisted sterilization and coagulation devices.
  • Contribution to interdisciplinary industrial-academic collaborations.
  • Patent-oriented translational engineering and biomedical innovation activities.

Research Contributions

Xinhua Zhang primarily involve the development of low-temperature plasma systems intended for medical and sterilization applications. Such technologies are increasingly investigated because of their potential to support pathogen inactivation, wound treatment, and coagulation procedures while minimizing thermal damage.[5] Zhang’s activities include engineering optimization for portable plasma systems and collaborative work involving medical technology industrialization initiatives.

Additional contributions include patent development and technology translation associated with healthcare engineering systems. The research portfolio also demonstrates engagement with applied quantum physics concepts and engineering methodologies designed to enhance the functionality of biomedical devices.[2] The interdisciplinary framework of these activities illustrates how applied physics principles may support emerging healthcare technologies.

  • Development of portable plasma sterilization devices.
  • Research on low-temperature plasma coagulation systems.
  • Integration of plasma engineering with biomedical device applications.
  • Contribution to patent generation and translational innovation.
  • Collaboration with industrial technology organizations for product development.

Publications

Indexed scientific publications provide evidence of scholarly engagement and participation in peer-reviewed academic dissemination. The publication profile associated with Xinhua Zhang includes research contributions in plasma science, applied physics, and biomedical engineering domains.[2] Published works and patents collectively support the dissemination and implementation of research outcomes across scientific and industrial contexts.

  1. Research articles related to low-temperature plasma sterilization systems.
  2. Studies involving quantum state control and surface plasmon physics.
  3. Engineering investigations associated with plasma coagulation devices.
  4. SCI-indexed publications connected to biomedical plasma technologies.
  5. Patent-oriented technological innovation documentation.

Research Impact

Xinhua Zhang includes indexed scholarly documents, citations, patent-related innovation activities, and industrial collaboration initiatives. Citation-based metrics indicate the visibility of published research within relevant scientific communities.[2] Additionally, participation in regional innovation projects reflects involvement in applied scientific development and translational engineering programs.

Patent development and technology commercialization activities represent another dimension of the research impact associated with Zhang’s work. These contributions support the broader objective of translating laboratory-based scientific research into deployable healthcare and sterilization technologies.[3] Such interdisciplinary innovation may contribute to future advancements in plasma medicine and biomedical instrumentation.

Award Suitability

The Innovative Research Award recognizes scientific activities demonstrating originality, interdisciplinary integration, and practical research implementation. Xinhua Zhang’s research activities align with these objectives through work involving plasma-assisted medical systems, quantum-related scientific investigation, and engineering-based translational innovation.[1]

His involvement in patent generation, regional research initiatives, industrial collaboration projects, and biomedical device development reflects a research profile characterized by both academic and practical relevance.[3] The combination of scholarly publications and applied engineering activities supports consideration for recognition within innovation-oriented scientific award programs.

Conclusion

Xinhua Zhang has contributed to interdisciplinary scientific research involving quantum information processing, surface plasmon studies, and low-temperature plasma biomedical engineering. His activities demonstrate engagement with translational technology development, collaborative research initiatives, and patent-oriented innovation processes.[2] Through the integration of applied physics principles and healthcare engineering methodologies, Zhang’s research profile reflects participation in contemporary scientific efforts focused on biomedical instrumentation and plasma-assisted medical technologies.

References

  1. Elsevier. (n.d.). Scopus author details: Xinhua Zhang, Author ID 58098441300. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=58098441300
  2. Xinhua Zhang,. et al. Photonics (2026). Surface Phonon Polariton-Quantum Dot Coupling in One-Dimensional Periodic Microstructures for Batch Quantum State Manipulation.
    https://www.mdpi.com/2304-6732/13/5/480
  3. Changzhou Institute of Technology. (n.d.). Academic and research profile associated with Xinhua Zhang.
    https://gdxy.czu.cn/2019/0315/c3781a68613/page.htm
  4. Processes (2023). The Biological Responses of Staphylococcus aureus to Cold Plasma Treatment.
    https://www.mdpi.com/2227-9717/11/4/1188
  5. Chiang Mai Journal of Science (2023). Transcriptome Study of Cold Plasma Treated Pseudomonas aeruginosa.
    https://epg.science.cmu.ac.th/ejournal/journal-detail.php?id=11716

Sergey Timashev | Quantum Science | Best Researcher Award

Published on by Applied Scientist

Prof. Sergey Timashev | Quantum Science | Best Researcher Award

Researcher at National Research Nuclear University MEPhI, Russia

Serge F. Timashev is a distinguished Russian physicist and physical chemist whose multidisciplinary research spans over six decades. Born in 1937 in Irbit, Sverdlovsk region, Russia, he has profoundly influenced fields ranging from nuclear physics and membrane science to geophysics and quantum mechanics. He earned his M.Sc. in Physics from Moscow State University in 1960, followed by a Ph.D. in Nuclear Physics in 1966, and a Doctor of Science in Physics and Mathematics in 1975. Dr. Timashev has held prestigious research positions in top Russian scientific institutes and is currently affiliated with the National Research Nuclear University MEPhI in Moscow. A pioneer in Flicker-Noise Spectroscopy and the physical chemistry of membrane processes, he has authored over 300 publications and several monographs. His seminal work has laid the foundation for innovative signal analysis techniques and energy-dependent separation methods. His contributions have earned him numerous accolades, including the Russian Federation Government Prize in Science and Technology and the honorary title of Honoured Scientist of the Russian Federation. Dr. Timashev’s career embodies scientific excellence, intellectual breadth, and a lifelong commitment to advancing knowledge in fundamental and applied sciences.

Professional Profile

Education

Serge F. Timashev’s academic foundation reflects his deep and broad engagement with the physical sciences. He commenced his formal studies at Moscow State University, where he earned a Master of Science degree in Physics in January 1960. Pursuing a keen interest in the nuclear domain, he completed his Ph.D. in Nuclear Physics at the Institute of Theoretical and Experimental Physics in Moscow in June 1966, presenting a dissertation on the mechanisms of direct nuclear reactions involving two-nucleon transfers. His academic journey culminated with a Doctor of Science degree in Physics and Mathematics in October 1975 from the Institute of Semiconductor Physics, part of the Siberian Branch of the USSR Academy of Sciences in Novosibirsk. This advanced work focused on optical and electric phenomena in semiconductors containing deep centers and in the presence of electric fields. His educational trajectory not only provided him with a profound understanding of classical and quantum physics but also positioned him to engage in complex, interdisciplinary research. Each milestone in his education expanded his scope, laying the groundwork for his contributions to diverse fields including quantum mechanics, membrane processes, and the analysis of chaotic systems.

Professional Experience

Throughout his career, Serge F. Timashev has held a series of prestigious research and academic positions across leading scientific institutions in Russia. His professional journey began at the Karpov Institute of Physical Chemistry, where he served as a Staff Scientific Researcher from 1963 to 1969. He then moved to the Institute of Physical Chemistry under the USSR Academy of Sciences, working as a Senior Scientific Researcher until 1979. During the next two decades (1979–1999), he led the Laboratory of Membrane Processes at the Karpov Institute, directing innovative studies in membrane chemistry and process engineering. From 1999 to 2018, he continued at the Karpov Institute as a Principal Researcher, spearheading advanced investigations in electrochemistry and signal analysis. Since 2018, Dr. Timashev has served at the National Research Nuclear University MEPhI (Moscow Engineering Physics Institute), where he remains an influential figure in theoretical and applied physical science research. His editorial contributions to major journals such as the Russian Journal of Physical Chemistry and Russian Journal of Electrochemistry further reflect his standing in the academic community. Across all his roles, Dr. Timashev has consistently demonstrated scientific leadership, mentoring, and a commitment to pushing disciplinary boundaries.

Research Interests

Dr. Serge F. Timashev’s research interests are exceptionally broad, encompassing multiple scientific domains, each characterized by depth and innovation. One of his most significant contributions is the development of Flicker-Noise Spectroscopy (FNS), a novel phenomenological method for extracting information from chaotic signals. FNS has applications ranging from signal processing in physics to earthquake prediction and cognitive neuroscience. In membrane science, Dr. Timashev pioneered the study of electropervaporation and switching conductivity in ion-exchange membranes, which has influenced the design of energy-dependent separation technologies. His work in physical chemistry includes groundbreaking theories in membrane transport, fluctuation metrology, and diffusion-controlled chemical kinetics. Dr. Timashev has also contributed significantly to quantum mechanics, where he proposed the concept of EM vacuum polarization to explain particle interactions and gravitation, challenging conventional notions of quantum reality. Moreover, his investigations in global environmental changes emphasize the thermodynamic interconnectedness of the biosphere with cosmic influences, introducing models that blend chemistry, ecology, and astrophysics. From nuclear reactions to fundamental quantum phenomena and ecological systems, Dr. Timashev’s interdisciplinary approach exemplifies a visionary scientific ethos driven by curiosity, rigor, and systemic understanding.

Research Skills

Dr. Timashev’s research skills reflect an extraordinary mastery of theoretical modeling, experimental design, and interdisciplinary integration. He has demonstrated expert competence in developing new scientific methodologies, such as Flicker-Noise Spectroscopy, which integrates statistical mechanics, time series analysis, and signal processing. In membrane science, his ability to correlate physicochemical principles with material properties has enabled the innovation of transport models that mimic biological systems. His theoretical capabilities are further evident in his quantum physics research, where he formulates phenomenological approaches to reinterpret particle behavior, vacuum interactions, and gravitational phenomena. Proficient in applying nonlinear thermodynamics to environmental systems, he also develops predictive models that account for solar-terrestrial interactions. Dr. Timashev is adept at crafting phenomenological theories supported by rigorous mathematical frameworks, as seen in his publications on chemical kinetics, nanosurface analysis, and stochastic processes. His use of advanced spectroscopy techniques, data interpretation methods, and experience with laboratory instrumentation further underscore his technical proficiency. Moreover, his extensive editorial experience across top scientific journals showcases his ability to critically evaluate cutting-edge research. Dr. Timashev’s skillset is marked by intellectual synthesis, mathematical rigor, and a lifelong dedication to advancing knowledge across complex scientific frontiers.

Awards and Honors

Serge F. Timashev’s distinguished contributions to science have been recognized through a series of prestigious awards and honors, reflecting both national and international acclaim. In 1995, he received the Prize of the Russian Federation Government in the field of Science and Technology, a testament to the practical impact and theoretical depth of his work. This was followed in 1996 by the award of the WD Wilson Visiting Fellowship from the Ernest Oppenheimer Memorial Trust in South Africa, highlighting his global scientific engagement and recognition. In 1998, Dr. Timashev was conferred the honorary title of Honoured Scientist of the Russian Federation, acknowledging his lifelong contributions to the advancement of physical chemistry and interdisciplinary research. Beyond formal honors, his status as a long-time editorial board member of several respected journals—including the Russian Journal of Physical Chemistry and the Russian Journal of Electrochemistry—demonstrates his leadership in shaping scholarly discourse. These accolades underscore his enduring influence on the scientific community and his reputation as a pioneering figure in multiple scientific domains. His awards not only affirm his past achievements but also serve as a reflection of his continued relevance in modern scientific inquiry.

Conclusion

The career of Serge F. Timashev stands as a remarkable testament to intellectual versatility, scientific integrity, and enduring curiosity. Across more than six decades of active research, he has made seminal contributions to diverse fields such as nuclear physics, membrane science, chemical kinetics, signal analysis, quantum mechanics, and environmental chemistry. His legacy is defined not only by his innovative theories—like Flicker-Noise Spectroscopy and Casimir polarization—but also by his unique ability to integrate insights across disciplinary boundaries. A prolific author of more than 300 scientific works and several foundational monographs, Dr. Timashev has deeply influenced both theoretical science and applied technologies. His work has been recognized with national awards and international fellowships, and he continues to contribute to the scientific community through mentorship, editorial roles, and ongoing research at MEPhI. In an era that increasingly values interdisciplinary collaboration and complex systems thinking, Dr. Timashev exemplifies the role of a modern scientist: deeply rooted in rigorous theory, yet unafraid to explore uncharted frontiers. His enduring contributions have not only advanced knowledge but also inspired a generation of scientists to pursue bold, integrative research.

Publications Top Notes

  1. Title: Erratum to: Non-Nucleon Metastable Excitations in Nuclear Matter and e– Catalysis As a Quark-Cumulative Mechanism for Initiating Low-Energy Nuclear Chemical Processes: Phenomenology
    Authors: Serge F. Timashev
    Year: 2024

  2. Title: Non-Nucleon Metastable Excitations in Nuclear Matter and e– Catalysis As a Quark-Cumulative Mechanism for Initiating Low-Energy Nuclear Chemical Processes: Phenomenology
    Author: Serge F. Timashev
    Year: 2024

  3. Title: Resolving the Paradox of the Dirac Equation through Phenomenology
    Author: Serge F. Timashev
    Year: 2024

  4. Title: FNS-Parameterization of Irregularities of Solar Activity Dynamic Variables
    Authors: S. A. Demin, V. A. Yunusov, S. F. Timashev, A. V. Minkin
    Year: 2023

  5. Title: Initiation of Artificial Radioactivity of Impurity Elements in a Lead Cathode under Conditions of a Glow Discharge
    Authors: S. F. Timashev, I. B. Savvatimova, S. S. Poteshin, N. I. Kargin, A. A. Sysoev
    Year: 2023

  6. Title: The Phenomenon of Artificial Radioactivity in Metal Cathodes under Glow Discharge Conditions
    Authors: S. F. Timashev, I. B. Savvatimova, S. S. Poteshin, S. M. Ryndya
    Year: 2022

  7. Title: Atom As an Open Dissipative System in the Basic Environment–the Electromagnetic Component of a Physical Vacuum: Phenomenology
    Author: Serge F. Timashev
    Year: 2022
    Citations: 1

  8. Title: On the Physical Nature of Quantum Mechanics and Gravitation: Phenomenology
    Author: Serge F. Timashev
    Year: 2022
    Citations: 4