Research Excellence Award

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.

External Links

• Scopus Author Profile

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