Topological Laser in Anomalous Quadrupole Topological Phases

Topological photonics shows considerable promise in revolutionizing photonic devices through the use of topological phases, leading to innovations like topological lasers that enhance light control. One of the recent breakthroughs is reducing the size of these systems by utilizing lower-dimensional boundary states, notably via higher-order topological phases. This paper presents the experimental demonstration of a topological laser in an anomalous quadrupole topological phase, an instance of higher-order phases. To facilitate this, a topological nanocavity with a quality factor near 6000 is engineered through a twisting operation. The topological nature of this system is validated by the calculation of nested Wannier centers and the emergency condition of corner states. The experimental observations reveal the manifestation of corner states and the achievement of single-mode pulsed laser, driven by an optical gain from multiple quantum wells at telecommunication wavelengths and a temperature of 4 K. A lasing threshold of 23 mu W and a cold quality factor of 1500 are deduced through rate equation. This work gives a new potential in the application of topological principles to advance nanophotonic technologies. This paper demonstrates a topological laser in anomalous quadrupole topological phases. High-quality topological cavities are engineered through twisting operations, and the system's topological nature is validated via nested Wannier center calculations and the emergency condition of corner states. Experimental results reveal single-mode pulsed lasing from a topological corner state, driven by quantum wells at telecommunication wavelengths. image