Institute of Applied Physics and Computational Mathematics | China
Dr. Han Xiaoying has made significant contributions to the fields of atomic and molecular physics as well as high-energy density physics, with a consistent research record spanning nearly two decades. Her work covers a wide spectrum—from early studies on electron-impact excitation and oscillator strengths in atoms such as helium, sodium, and oxygen ions, published in leading journals like Physical Review A and Journal of Physics B, to the development of advanced simulation models for hot dense plasmas under non-local thermodynamic equilibrium (NLTE) conditions. She has been instrumental in proposing the MAICRM model for rapid plasma spectra simulation and has recently advanced the field through deep learning surrogate models to solve time-dependent NLTE absorption and emission spectra. In addition, her collaborations include pioneering research on x-ray source dynamics for in situ diffraction measurements and precise measurements of radiative albedo in hohlraum experiments, reported in high-impact journals such as Physics of Plasmas and Matter and Radiation at Extremes. Overall, Dr. Han’s research combines strong theoretical foundations with modern computational approaches, reinforcing her reputation as a leading expert in atomic physics and plasma diagnostics.
Profile: Scopus | Google Scholar | Orcid
Featured Publications
"Deep learning surrogate models to solve time-dependent NLTE absorption and emission spectra"
"Self-consistent and precise measurement of time-dependent radiative albedo of gold based on specially symmetrical triple-cavity Hohlraum"
"Early-Time Harmonic Generation from a Single-Mode Perturbation Driven by X-Ray Ablation"
"An effective method to calculate the electron impact excitation cross sections of helium from ground state to a final channel in the whole energy region"
"MAICRM: A general model for rapid simulation of hot dense plasma spectra"