Shanxi University | China
Prof. Xin-Jian Wen is a distinguished theoretical physicist whose research focuses on the properties of strongly interacting matter, the mechanism of QCD phase transitions, and the behavior of strange quark matter under extreme conditions such as high density and strong magnetic fields. With an h-index of 11, 43 published documents, and 567 citations from 352 sources, his work has made a significant contribution to advancing quantum chromodynamics (QCD) phenomenology at finite temperature and density. A graduate of Shaanxi Normal University and the Chinese Academy of Sciences, Prof. Wen has developed innovative models to study the stability of strange quark matter, strangelets, and the quark-hadron mixed phase in compact stars. His pioneering investigations using the quasiparticle model and multi-reflection expansion approach have provided new insights into surface tension effects, magnetic field interactions, and color-flavor-locked (CFL) phases. Prof. Wen has collaborated with several leading physicists and published influential papers in top-tier journals such as Physical Review D and Physical Review C. As a full professor at the Institute of Theoretical Physics, Shanxi University, he continues to advance theoretical research in QCD and compact star physics.
Profiles : Scopus | Orcid
Featured Publications
Zhang, J., & Wen, X.-J. (2025, September 12). Stability analysis of magnetized quark matter in Tsallis statistics. Universe.
Jiang, X.-W., & Wen, X.-J. (2025, June 20). Deconfinement of magnetized quark matter in a quasiparticle description. International Journal of Modern Physics A.
Niu, Y.-H., Wen, X.-J., & Singha, S. (2025, January). Tensor condensate accompanied by chiral transition in a strong magnetic field. Advances in High Energy Physics.
Su, S.-Z., Zhao, Y.-Y., & Wen, X.-J. (2025, January 31). The finite volume effects of the Nambu–Jona–Lasinio model with the running coupling constant. Journal of Physics G: Nuclear and Particle Physics.
Zhang, J., & Wen, X.-J. (2024, November 26). QCD phase transition with nonextensive NJL model in the strong magnetic field. Physical Review D.
He, R., & Wen, X.-J. (2024, June 1). Anisotropy and paramagnetism of QCD matter with an anomalous magnetic moment. Journal of Physics G: Nuclear and Particle Physics.
Wen, X.-J., & Zhang, J. (2024, February 12). Thermal effect in hot QCD matter in strong magnetic fields. Physical Review C.
Wang, Y., & Wen, X.-J. (2024, January 8). Isospin asymmetric matter in uniform and nonuniform strong magnetic fields. Physical Review C.
He, Y.-Y., & Wen, X.-J. (2023, April 24). Medium effect on anisotropic surface tension of magnetized quark matter. Physical Review D.
He, R., & Wen, X.-J. (2022, December 29). Effect of anomalous magnetic moment on the chiral transition at zero temperature in a strong magnetic field. Physical Review D. amics of PNJL model at zero temperature in a strong magnetic field. Physical Review D.
Yang, L., & Wen, X.-J. (2021, December 8). Compressibility of quark matter under strong magnetic field in the NJL model. Physical Review D.
Su, S.-Z., & Wen, X.-J. (2021, July 1). Influence of magnetic fields on the stability and the phase transition of quark matter in the Nambu–Jona–Lasinio model. Journal of Physics G: Nuclear and Particle Physics.
Wen, X.-J., He, R., & Liu, J.-B. (2021, May 17). Effect of the anomalous magnetic moment on the chiral transition in a strong magnetic field. Physical Review D.
Wang, Y., & Wen, X.-J. (2020, October 1). Magnetized hot and dense quark matter in the Polyakov Nambu–Jona–Lasinio model. Journal of Physics G: Nuclear and Particle Physics.