Observation of Unidirectional Bound States in the Continuum Enabled by Topological Defects

Unidirectional radiation is important for various optoelectronic applications. Many unidirectional emitters exist, but they all rely on placing materials or structures that forbid outgoing waves, i.e. mirrors, on the other side. Here, we theoretically propose and experimentally demonstrate a class of resonances in photonic crystal slabs, which only radiate towards a single side with no mirror placed on the other --- we call them "unidirectional bound states in the continuum". These resonances are found to emerge when a pair of half-integer topological charges in polarization, each representing a circularly-polarized resonance of opposite helicities, bounce into each other in the momentum space. We experimentally achieve single-sided quality factors as high as $1.6\times 10^5$ in the telecommunication regime, which is equivalent to asymmetric ratio of 27.7 dB. Our work represents a vivid example of applying topological principles to improve optoelectronic devices, such as grating couplers, photonic-crystal surface-emitting lasers, and light detection and ranging.