Assoc. Prof. Dr Yousef Abou-Ali | Plasma Physics | Best Researcher Award

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

scholar

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