Department of Physics, Damascus University, Syria
🔬👨🎓 Yousef Abou-Ali is an Associate Professor of Physics at the University of Damascus, Syria. Born on September 23, 1967, he has a strong background in laser-plasma physics and has made significant contributions to the field. With expertise in optics and laser-plasma diagnostics, Yousef has published numerous papers in reputable journals. 🌟
Professional Profile
Education 🎓
– PhD in Laser-Plasma Physics, University of York, UK (2004) 💡– MSc by Research in Laser-Plasma Physics, University of York, UK (2000) 🔍– Diploma of High Studies in Electronics of Solid State, Aleppo University, Syria (1992) 📖– BSc in Physical Sciences (Nuclear), Aleppo University, Syria (1991)
Experience 💼
– Associate Professor, University of Damascus, Syria (2019-present) 📚– Lecturer, University of Damascus, Syria (2004-2018) 👨🏫– Teaching courses in plasma physics, mechanics, laser applications, and physics of sound 🌊– Coordinator of Laser and Optics laboratory 👨🔬– Research Fellow, INTI International University Malaysia (2023-2025)
Research Focus 🔍
🔬💡 Yousef’s research focuses on laser-plasma physics, X-ray lasers, and plasma diagnostics. He has published numerous papers on these topics and has expertise in optics and laser-plasma diagnostics. His research interests include:
Awards and Honors 🏆
– Referee, Institute of Physics Journals (IOP) (2004-present) 📚– Member, Syrian Association for Fundamental and Natural Sciences (SAFNS) (2005-present) 🌟– Head of Basic Sciences and University Requirements Department, IUST, Syria (2007-2015)
Publication Top Notes
1. Deuteron beam fluence emitted from dense plasma focus: Comparative investigation and simulation 🔍
2. Estimation of alpha exposure on CR-39 detector using a UV-VIS spectrophotometer 💡
3. Comparison of the measured and simulated D-D fusion neutron yield from the plasma focus using Lee model 🔬
4. Numerical study on deuteron beams properties generated from dense plasma focus devices in terms of D2 gas pressure using Lee model code 📊
5. Numerical experiments on the total D–D fusion neutron yield versus deuterium pressure for different energy plasma focus devices using the Lee model code 💻
6. Studying the possibility of using the optical transmittance to estimate density of the alpha particle tracks on CR-39 detector 🔍
7. Calculations of Ne-like Ni collisionally pumped laser as function of target length and delay time and some other parameters using simulation codes 📊
8. A computational investigation of nickel-like dysprosium collisionally pumped laser 🔬
9. Pumping laser energy absorption in X-ray laser experiments 💡
10. Quantitative simulations of short pulse x-ray laser experiments 🔍
11. Comparison of simulated and experimental time resolved emission for a Ne-like nickel x-ray laser 🔬
12. Measurement of the duration of X-ray lasing pumped by an optical laser pulse of picosecond duration 🔍
13. Pumping laser energy absorption in X-ray laser experiments 📊
14. Measurement of Gain Duration for Ne-like Ni and Ni-like Ag 🔬
15. Energy absorption in x-ray laser experiments 💡
16. Time resolved emission for a Ne-like nickel X-ray laser 🔍
17. Measurement of the duration of X-ray lasing pumped by Vulcan CPA 🔬
18. Experiments and simulations of short-pulse laser pumped extreme ultra-violet lasers 🔍
19. Efficiency of 1.5- to 4.5-keV x-ray production from laser plasmas 💡
20. Approaching the transform limit for X-ray laser pulses 🔍
21. Time-resolved measurements of the transient X-ray laser emission 🔬
22. Saturated and Short Pulse Duration X-Ray Lasers 🔍
23. A review of X-ray laser development at Rutherford Appleton Laboratory 🔬
24. Efficiency of 1.5 – 4.5 keV X-ray production from 2 ps duration KrF laser pulses incident onto solid targets 💡
25. Collisionless shock and supernova remnant simulations on VULCAN 🔍
26. Response to ‘Comment on ‘Collisionless shock and supernova remnant simulations on VULCAN’ 🔬
27. Supernova remnant simulation experiments on VULCAN 🔍
28. Saturated x-ray lasers at 196Å and 231Å and imaging of the Ne-like Ni XRL
Conclusion
Based on the provided information, the candidate demonstrates strengths in teaching and academic background. However, to further strengthen their application for the Best Researcher Award, it would be beneficial to highlight research achievements, interdisciplinary collaborations, and international recognition. Providing more specific examples or metrics related to these areas could make their application more compelling ¹.