Chien-Cheng Kuo is a physicist currently serving as Associate Vice President of Academic Affairs and Professor in the Department of Physics at National Sun Yat-sen University, Taiwan. Dr. Kuo earned his Ph.D. in Physics from National Taiwan University in 2000, with a dissertation on the interrelation between crystalline structures, alloy composition, and magnetic properties in ultrathin films. He has held significant academic and administrative roles at National Sun Yat-sen University, including Director of the Office of Admission Strategy and Director of the International Ph.D. Program for Synchrotron and Neutron Beam Applications. Internationally, he has conducted research at renowned institutions such as Ames National Laboratory in the USA and the Max-Planck Institute of Microstructure Physics in Germany.

Dr. Kuo's expertise spans various areas, including nanostructure physics, spintronics materials, graphene, two-dimensional structures, and synchrotron radiation research. His research extensively employs techniques such as molecular-beam epitaxy, scanning tunneling microscopy, and photoemission spectroscopy. He has published extensively in high-impact scientific journals on topics such as magnetic nanostructures, quantum interference, and the electronic properties of graphene. Beyond academia, Dr. Kuo actively contributes to the scientific community, holding prominent positions such as Vice President of the Physical Society of Taiwan and serving as a reviewer and editorial member for several prestigious journals.

Chien-Cheng Kuo's lab focuses on investigating the intriguing phenomena of nanostructured physics, employing cutting-edge techniques for atom-by-atom analysis of nanoscale materials. This advanced research utilizes a wide range of sophisticated methods, such as scanning tunneling microscopy (STM) and spectroscopy (STS), enabling direct visualization of atomic surfaces and precise probing of electronic properties. The lab also uses photon-excited electron microscopy (PEEM) to study how light interacts with matter, revealing electron behaviors in low-dimensional materials. Additionally, Kerr microscopy helps explore magneto-optical properties, offering insights into the magnetic features of van der Waals structures. Through these innovative methodologies, the lab seeks to enhance knowledge about various low-dimensional materials and their distinctive qualities, potentially opening doors for novel applications in nanotechnology and materials science.