Matter in nature is composed of three fundamental particles: electrons, protons, and neutrons. Although all matter is made up solely of these particles, they can exhibit a wide range of properties and manifest in various forms, such as solids, liquids, conductors, insulators, superfluids, and magnets. According to the emergence principle in condensed matter physics, the diverse properties of matter arise from the different ways in which these particles are organized. These arrangements are referred to as the orders of matter (from the book by Xiao-Zhang Wen, MIT). Different orders in a system lead to the manifestation of various physical properties—magnetic, electrical, and mechanical—under different conditions. I am particularly interested in investigating these physical properties within interacting condensed matter systems, including spin systems and topological materials. To explore different orders—both topological and non-topological—as well as the transitions between them, I sometimes employ fundamental concepts from quantum information theory. My research involves studying the magnetic and electrical properties of these systems, including their ground states, excitation behaviors, thermal properties, and electrical responses, using tools from many-particle physics. To better illustrate the work I do with my students and colleagues, I have included recent publications from our group at the bottom of this page. Please click the link for more detailed information. If you have any questions, discussions, or suggestions regarding our works, please feel free to contact me via email.
Topology and magnetism, Frustrated spin lattices, Thermoelectric materials.
Magnetism in condensed matter physics
Statistical mechanics
Quantum Physics
Quantum mechanics
Electromagnetism
Condensed matter physics
Thermodynamics
Developed by the IASBS Computer Centre
