Dr. Muhammad Bilal | Editorial Board Member

Published on by Physics and Quantum Physics

Dr. Muhammad Bilal | Editorial Board Member

Shanghai University | China

Dr. Muhammad Bilal is an applied mathematics researcher at Shanghai University whose work focuses on nonlinear wave theory, optical solitons, plasma physics, and computational methods for complex dynamical systems. With a strong publication record comprising over 40 documents, more than 1,900 citations, and an h-index of 23, he has established himself as a significant contributor to mathematical physics and nonlinear wave propagation. He completed his advanced education in applied and computational mathematics and has accumulated extensive research experience through collaborative projects in wave dynamics, optical fiber modeling, modulation instability, and analytical methods for nonlinear differential equations. His research interests span nonlinear Schrödinger systems, shallow water wave models, ferromagnetic materials, fractional models, and stability analysis across diverse physical systems. Dr. Bilal has contributed widely cited analytical techniques and exact solution frameworks that have enhanced theoretical understanding and computational modeling in optical communication and fluid dynamics. His work has appeared in reputable international journals such as Mathematical Methods in the Applied Sciences, Results in Physics, Optical and Quantum Electronics, Modern Physics Letters B, and IEEE Access. He has also been recognized for his scientific impact through multiple high-quality publications and his growing influence in applied mathematics research.

Profile : Google Scholar

Featured Publications

Bilal, M. A., Zeeshan, M., Riaz, Q., Shahzad, M. K., Jabeen, H., & Haider, S. A., et al. (2021). Protocol-based deep intrusion detection for DoS and DDoS attacks using UNSW-NB15 and Bot-IoT datasets. IEEE Access, 10, 2269–2283.

Bilal, M., Seadawy, A. R., Younis, M., Rizvi, S. T. R., & Zahed, H. (2021). Dispersive propagation wave solutions to unidirectional shallow water wave Dullin–Gottwald–Holm system and modulation instability analysis. Mathematical Methods in the Applied Sciences, 44(5), 4094–4104.

Bilal, M., Seadawy, A. R., Younis, M., Rizvi, S. T. R., El-Rashidy, K., & Mahmoud, S. F. (2021). Analytical wave structures in plasma physics modelled by the Gilson-Pickering equation using two integration norms. Results in Physics, 23, 103959.

Younis, M., Sulaiman, T. A., Bilal, M., Rehman, S. U., & Younas, U. (2020). Modulation instability analysis and optical solutions to the modified nonlinear Schrödinger equation. Communications in Theoretical Physics, 72(6), 065001.

Younis, M., Younas, U., Rehman, S. U., Bilal, M., & Waheed, A. (2017). Optical bright–dark and Gaussian soliton with third-order dispersion. Optik, 134, 233–238.

Mr. Weijiang Xu | Best Researcher Award

Published on by Physics and Quantum Physics

Mr. Weijiang Xu | Best Researcher Award

Guilin University of Electronic Technology | China

Dr. Weijiang Xu is a Lecturer at the School of Optoelectronic Engineering, Guilin University of Electronic Technology. He earned his Doctor of Science (2024) and Master of Science (2018) in Physics from Harbin Institute of Technology, following his Bachelor’s degree from Lingnan Normal University in 2016. His research centers on optical fiber sensors, quantum dot photonics, and upconversion luminescence for multifunctional sensing applications. Dr. Xu has authored 17 scientific documents with over 120 citations and maintains an h-index of 8, reflecting his growing influence in the field of optical materials and photonic sensing. His representative works, published in leading journals such as Optics Express, Optics Letters, Journal of Lightwave Technology, and Optics Communications, explore innovative fiber-based devices for temperature, curvature, and flow sensing. He has also contributed to the development of several patented optical fiber sensing technologies in China. Dr. Xu’s recent advancements include bubble-tunable and calibration-free optical fiber sensors employing quantum dots-filled liquid cores. His research continues to bridge nanomaterials with optical engineering for advanced environmental and biomedical sensing. With a record of impactful publications and technological innovation, Dr. Xu is emerging as a promising scholar in the field of optoelectronic sensing.

Profile :  Scopus 

Featured Publications

Xu, W., Li, Y., Shang, J., Wang, Y., Hou, L., Liu, Y., & Qu, S. (2022). Optical fiber sensor based on upconversion luminescence for synchronous temperature and curvature sensing. Optics Express, 30(18), 33136–33136.

Xu, W., Qu, J., Liu, Y., Bai, J., Li, Y., & Qu, S. (2023). Optical fiber inclinometer with dynamically controllable excitation length of quantum dots liquid-core waveguide based on a photo-controlled bubble. Optics Letters, 48(6), 1403–1406.

Xu, W., Qu, J., Liu, Y., Bai, J., Li, Y., & Qu, S. (2023). A calibration-free fiber sensor based on CdZnSe/ZnSe/ZnS quantum dots for real-time monitoring of human thermal activities. Measurement, 206, 112315.

Xu, W., Liu, Y., Li, Y., & Qu, S. (2024). Horizontal clinometer based on a movable bubble in the arc-shaped quantum dots liquid cavity. Journal of Lightwave Technology, 42(6), 2193–2199.

Qu, J., Zhang, Y., Ling, M., & Xu, W.* (2025). Heat-typed fiber liquid flow sensor with wide sensing range and high sensitivity. Journal of Lightwave Technology, 43(1), 369–375.