Didem Ketenoglu | Physics | Best Researcher Award

Published on by Scientific World Research Awards

Best Researcher Award

Didem Ketenoglu
Didem Ketenoglu
Affiliation Ankara University
Country Turkey
Scopus ID 54408485500
Documents 19
Citations 229
h-index 6
Subject Area Physics
Event Scientific World Research Awards
ORCID 0000-0002-2382-1413

Didem Ketenoglu is a physicist affiliated with Ankara University whose research spans synchrotron radiation, X-ray spectroscopy, accelerator science, advanced instrumentation, and computational optimization. Her scholarly contributions support the development of analytical techniques and scientific infrastructure used across modern physics and materials science research.[1]

Abstract

Didem Ketenoglu has established a research profile in physics with particular emphasis on synchrotron radiation, X-ray Raman scattering, spectroscopy instrumentation, accelerator technologies, and advanced computational optimization methods. Her publications address the design and improvement of scientific instruments, lithium-ion battery characterization, free-electron laser optimization, and non-destructive analytical techniques. Through interdisciplinary collaborations, she has contributed to developments in beamline optimization, artificial intelligence applications, and materials characterization. Her research supports the advancement of experimental physics by improving analytical precision and enhancing the capabilities of modern synchrotron facilities used in scientific and industrial investigations.[2]

Keywords

Physics, Synchrotron Radiation, X-Ray Spectroscopy, Accelerator Science, Beamline Optimization, Scientific Instrumentation, Artificial Intelligence, Materials Characterization.

Introduction

Modern physics increasingly relies on advanced instrumentation and analytical methods. Ketenoglu’s research contributes to these areas through studies focused on synchrotron radiation facilities, spectroscopy systems, and computational approaches for optimizing experimental performance.[3]

Research Profile

Her academic work spans physics engineering, X-ray spectroscopy, synchrotron applications, battery materials research, and accelerator technologies. She has participated in both experimental and computational investigations supporting scientific infrastructure development.[1]

Research Contributions

Notable contributions include X-ray Raman spectroscopy developments, resonant inelastic X-ray scattering instrumentation, synchrotron beamline optimization, and artificial intelligence-assisted cultural heritage analysis. These studies demonstrate interdisciplinary applications of physics research.[2]

Publications

  • DFT and ATR-FTIR Investigation of LiPF₆-Based Carbonate Electrolytes for Lithium-Ion Batteries (2026).
  • Optimization of Synchrotron Radiation Parameters Using Swarm Intelligence and Evolutionary Algorithms (2024).
  • A General Overview and Comparative Interpretation on XPS, XAS, and XRS (2022).

Research Impact

Her publications contribute to the improvement of analytical methodologies used in materials science, energy research, and accelerator-based investigations. The research supports enhanced experimental capabilities and broader scientific applications.[4]

Award Suitability

The combination of publication productivity, interdisciplinary collaboration, and contributions to scientific instrumentation aligns well with the objectives of the Best Researcher Award, recognizing sustained scholarly activity and research advancement in physics.[5]

Conclusion

Didem Ketenoglu’s research reflects continued engagement in experimental physics, spectroscopy, and accelerator science. Her work contributes to the development of advanced analytical tools and supports innovation in scientific research infrastructure.

References

  1. ORCID. (2026). Didem Ketenoglu ORCID Record.

    https://orcid.org/0000-0002-2382-1413

  2. Ketenoglu, D. et al. (2026). DFT and ATR-FTIR Investigation of LiPF₆-Based Carbonate Electrolytes.

    https://doi.org/10.1016/j.electacta.2026.148834

  3. Ketenoglu, D. et al. (2024). Optimization of Synchrotron Radiation Parameters Using Swarm Intelligence and Evolutionary Algorithms.

    https://doi.org/10.1107/S1600577524000717

  4. Ketenoglu, D. (2022). A General Overview and Comparative Interpretation on XPS, XAS, and XRS.

    https://doi.org/10.1002/xrs.3299

  5. Elsevier. (n.d.). Scopus Author Details: Didem Ketenoglu, Author ID 54408485500.

    https://www.scopus.com/authid/detail.uri?authorId=54408485500

Vasileios Lembessis | Physics | Best Researcher Award

Published on by Scientific World Research Awards

Prof. Vasileios Lembessis | Physics | Best Researcher Award

Professor | King Saud University | Saudi Arabia

Dr. Vassilis E. Lembessis is a leading physicist internationally recognized for his influential contributions to quantum optics, laser cooling and trapping, twisted light beams, and plasmonics. His research primarily investigates the interaction between atoms and structured light fields, exploring how the angular momentum, phase, and topology of light influence atomic dynamics and quantum behavior. With an extensive citation record exceeding 1,700 citations, an h-index of 18, and an i10-index of 34, his scientific work has profoundly shaped the theoretical and experimental frontiers of modern optical physics.A central theme of Dr. Lembessis’s research is the manipulation of ultracold atoms and quantum gases using complex optical fields. His highly cited papers, such as “Optical Ferris Wheel for Ultracold Atoms” and “Atoms in Complex Twisted Light,” have introduced groundbreaking models for controlling atomic motion through optical vortices and Laguerre–Gaussian beams. These studies have provided fundamental insights into optical angular momentum transfer, light-induced forces, and coherent control in atomic systems.Dr. Lembessis has also advanced the understanding of surface plasmon optical vortices, spin–orbit coupling in light beams, and light-induced torque in Bose–Einstein condensates, bridging the gap between classical electromagnetism and quantum phenomena. His research reveals how tailored light structures can generate new forms of atomic trapping, guiding, and rotation—paving the way for emerging technologies in quantum manipulation, photonic nanodevices, and precision measurement.His collaborative work with prominent researchers across global institutions continues to deepen the theoretical framework of light–matter interactions, addressing phenomena such as enhanced quadrupole effects, atomic vortex generation, and plasmonic field singularities. These investigations have implications not only for fundamental quantum theory but also for practical advancements in quantum computing, optical communications, and nanophotonics.Through his innovative and interdisciplinary approach, Dr. Vassilis E. Lembessis has become a prominent figure in contemporary physics, consistently expanding the boundaries of light–matter science and inspiring future exploration into quantum technologies and structured photonic systems that define the next generation of optical and quantum research.

Profiles: ORCID | Google Scholar

Featured Publications

  1. Jaouadi, A., Lyras, A., & Lembessis, V. E. (2025). Towards a Twisted Atom Laser: Cold Atoms Released from Helical Optical Tube Potentials. Photonics, 12(10), 999.

  2. Lembessis, V. E., Yuan, J., Köksal, K., & Babiker, M. (2025). Time dilation effects in micron-size rotating optical Ferris-wheel traps. Physical Review A.

  3. Babiker, M., Köksal, K., Lembessis, V. E., & Yuan, J. (2024). Intrinsic angular momentum, spin and helicity of higher-order Poincaré modes. Journal of Optics.

  4. Lembessis, V. E., & Andrews, D. L. (2024). Forces in the Interaction of Light with Matter. Applied Sciences.

  5. Alsaawi, N., Lembessis, V. E., Lyras, A., Babiker, M., & Yuan, J. (2024). Helicity of magnetic fields associated with non-relativistic electron vortex beams. Journal of Physics A: Mathematical and Theoretical.

Here are the APA-formatted references for the listed publications by Vassilis E. Lembessis and co-authors. Note: I couldn’t locate reliable citation counts or a verified h-index for each article at this time, so those fields are left blank.