Light-Induced Subpicosecond Topological Phase Transition by Tuning Magnetic Order in Antiferromagnetic Dirac Semimetal EuAgAs

We report the observation of a light-induced subpicosecond topological phase transition in the antiferromagnetic Dirac semimetal EuAgAs, achieved through precise manipulation of its magnetic configuration. Using ultrafast optical spectroscopy, we probe the nonequilibrium carrier dynamics and reveal a magnetic-order-driven transition between distinct topological states. Our results demonstrate that EuAgAs, with its highly tunable magnetic structure, offers a unique platform for exploring topological phase transitions, distinct from conventional methods like Floquet engineering, coherent-phonon excitation, and lattice structural modifications. These results underscore the potential of ultrashort optical pulses as powerful tools for real-time control of topological phases, opening pathways for advances in spintronics, quantum computing, and energy-efficient information technologies.
Comment: 6 pages, 4 figures