Our research is centered around the intriguing field of photoionization studies of multiply charged ions, a topic that holds great significance in the realms of both fundamental science and practical applications. Delving into this area allows us to unravel the intricate relationships between electrons, shedding light on electron correlation and the influence of relativistic effects. These insights are invaluable for understanding the behavior of matter in extreme conditions and in diverse environments. Moreover, the data derived from our photoionization investigations find extensive use in atmospheric and astrophysical research, aiding in the comprehension of complex natural phenomena and celestial bodies. These applications underpin the relevance and impact of our work, reaching beyond the laboratory into the broader scientific community. Our approach involves the utilization of sophisticated many-body techniques, enabling us to analyze photoionization and scattering from atoms and molecules in intricate detail. Additionally, we explore the electronic structure and dynamic properties of high atomic number (Z) elements, contributing to a deeper understanding of their behavior and reactivity. Our research thus encapsulates both the pursuit of fundamental knowledge and its practical implications in various fields.
