Assistant Professor at xian jiaotong university, China.
Dr. Muqaddar Abbas 👨🔬 is an Assistant Professor at the School of Physics, Xi’an Jiaotong University 🇨🇳. Born on November 8, 1985 🇵🇰, he specializes in Quantum Optics and Information Physics 🌌. With a strong academic foundation and over a decade of research and teaching experience, Dr. Abbas has published extensively in prestigious journals 📚 and actively participates in global conferences 🌍. His work explores cutting-edge quantum technologies including cavity quantum electrodynamics and photonic effects 💡. Beyond academia, he enjoys badminton 🏸, hiking 🥾, and reading 📖. He is known for his collaborative spirit and scientific curiosity.
Professional Profile:
Scopus
🏅Suitability for Best Researcher Award – Assist. Prof. Dr. Muqaddar Abbas
Dr. Muqaddar Abbas exemplifies excellence in research through his deep engagement with cutting-edge topics in Quantum Optics and Information Physics. With a Ph.D. focused on nonlinear quantum systems and over a decade of progressive academic roles, he has consistently contributed to both the theoretical and applied facets of quantum science. His international exposure, interdisciplinary collaborations, and strong publication record in reputed journals strengthen his candidature.
📘 Education & Experience
-
🧑🎓 Ph.D. in Physics (Quantum Optics) – COMSATS University Islamabad, Pakistan (2012–2017)
📘 Thesis: Effect of Kerr Nonlinearity
-
📘 M.Phil. in Physics – Quaid-i-Azam University Islamabad (2009–2011)
🧪 Thesis: Non-Markovian Dynamics
-
📘 M.Sc. in Physics – Quaid-i-Azam University Islamabad (2006–2008)
-
📘 B.Sc. in Physics & Math – University of Punjab, Lahore (2004–2006)
💼 Professional Experience
-
👨🏫 Assistant Professor, Xi’an Jiaotong University (2021–Present)
-
🔬 Senior Scientific Officer, COMSATS University Islamabad (2018–2021)
-
🧑🔬 Research Associate, COMSATS University Islamabad (2011–2018)
📈 Professional Development
Dr. Abbas continually enhances his academic and professional expertise through active participation in international conferences and workshops 🌐, including presentations in Germany 🇩🇪, China 🇨🇳, and Pakistan 🇵🇰. He has contributed to scientific events like ICEQT, ICQFT, and Quantum 2020 📡. His technical toolkit includes MATLAB, Mathematica, Python, and LaTeX 💻. Additionally, his soft skills—teamwork, leadership, and problem-solving—complement his technical acumen 🧠. With fluency in English and Urdu, and basic Chinese skills 🗣️, he collaborates effectively across global platforms. His commitment to learning ensures he remains at the forefront of quantum research and education 📚🌟.
🔬 Research Focus Area
Dr. Muqaddar Abbas’s research is rooted in Quantum Optics and Quantum Information Science 🌠. His work spans advanced areas such as Cavity Quantum Electrodynamics, Bose-Einstein Condensates, Cavity-Optomechanics, and Electromagnetically Induced Transparency (EIT) 🔍. He also explores modern phenomena like the Photonic Spin Hall Effect and Rydberg Atom Control Theory 🌀. His aim is to develop innovative solutions in optical memory, sensing, and slow/fast light control 📡. By combining theoretical modeling with experimental insight, he contributes to advancing quantum technologies for the future of communication and computation 💡🧬.
🏅 Honors & Awards
-
🏆 Research Productivity Awards – COMSATS University (2016–2018)
-
🎓 Razmi Fellowship – Quaid-i-Azam University (2009–2010)
-
🎖️ Merit Fellowship – Quaid-i-Azam University (2010–2011)
Publication Top Notes
📘 1. Double-frequency photonic spin Hall effect in a tripod atomic system
Authors: M. Abbas, Y. Wang, F. Wang, P. Zhang, H.R. Hamedi
Journal: Optics Communications (2025)
Summary:
This paper reports the realization of a double-frequency photonic spin Hall effect (PSHE) using a tripod atomic configuration. By carefully designing the atomic energy levels and their coupling with external fields, the authors demonstrate that two distinct frequency components of the PSHE can be produced and controlled. This study offers new avenues for developing advanced photonic spintronic devices with enhanced frequency diversity and control.
📘 2. Coherent- and dissipative-coupling control of photonic spin Hall effect in cavity magnomechanical system
Authors: A. Munir, M. Abbas, Ziauddin, C. Wang
Journal: Optics and Laser Technology (2025)
Summary:
This work explores how both coherent and dissipative couplings in a cavity magnomechanical system can be exploited to control the PSHE. Through theoretical modeling and simulations, the paper demonstrates how coupling strengths and detunings impact the spin-dependent light deflection, providing a flexible mechanism for dynamic photonic modulation.
📘 3. Tuning the Photonic Spin Hall Effect through vacuum-induced transparency in an atomic cavity
Authors: M. Abbas, Y. Wang, F. Wang, H.R. Hamedi, P. Zhang
Journal: Chaos, Solitons & Fractals (2025)
Citations: 1
Summary:
The study presents a scheme to enhance and tune the PSHE using vacuum-induced transparency (VIT) in a cavity containing atomic media. The authors analyze how quantum interference and vacuum field interactions can be manipulated to control spin-dependent beam shifts, offering promising applications in quantum metrology and optical switches.
📘 4. Manipulation of the photonic spin Hall effect in a cavity magnomechanical system
Authors: M. Abbas, G. Din, H.R. Hamedi, P. Zhang
Journal: Physical Review A (2025)
Summary:
This article investigates the manipulation of the PSHE within a hybrid magnomechanical system, where magnons and phonons interact with cavity photons. The authors demonstrate the ability to control the light’s spin-dependent trajectory via external magnetic fields and mechanical resonances, offering novel functionalities for nonreciprocal light propagation.
📘 5. Coherent control of Surface Plasmon Polaritons Excitation via tunneling-induced transparency in quantum dots
Authors: F. Badshah, M. Abbas, Y. Zhou, H. Huang, Rahmatullah
Journal: Optics and Laser Technology (2025)
Citations: 7
Summary:
This paper proposes a method to control the excitation of surface plasmon polaritons (SPPs) in quantum dot systems using tunneling-induced transparency (TIT). Through careful modulation of electron tunneling parameters, the authors achieve precise control over SPP excitation, enhancing prospects for quantum plasmonic circuits and sensing applications.
📘 6. Tunable photonic spin Hall effect in a tripod atom-light configuration
Authors: M. Abbas, P. Zhang, H.R. Hamedi
Journal: Physical Review A (2025)
Summary:
This study introduces a tunable PSHE mechanism based on a tripod atomic level structure interacting with light. By adjusting the control field parameters, the authors show how the spin-dependent deflection angle and direction of the transmitted beam can be precisely regulated, enabling potential use in spin-controlled photonic routing systems.
📘 7. Nonreciprocal cavity magnonics system for amplification of photonic spin Hall effect
Authors: A. Munir, M. Abbas, C. Wang
Journal: Chaos, Solitons & Fractals (2025)
Summary:
This article explores a nonreciprocal cavity magnonics system that significantly amplifies the PSHE. By leveraging nonreciprocal magnon-photon coupling, the system allows for enhanced spin-controlled light propagation. The approach provides a promising framework for designing isolators and circulators in integrated quantum optical devices.
🧾 Conclusion
Dr. Muqaddar Abbas’s work stands at the forefront of quantum technology research, with practical implications for the future of secure communication, quantum computing, and photonic systems. His sustained publication record, international collaborations, research excellence, and mentorship contributions make him a deserving recipient of the Best Researcher Award.