手性(物理)
物理
对称性破坏
实现(概率)
齐次空间
量子力学
手征对称破缺
光子学
平面的
对称(几何)
圆二色性
束缚态
磁化
平面手性
理论物理学
领域(数学)
拓扑(电路)
显式对称破缺
凝聚态物理
超材料
自发对称破缺
镜像对称
作者
Maohua Gong,Qiutong Zhen,Chunquan Peng,Yujie Tang,涂清安 Qing''An Tu,Peng Hu,Peiheng Zhou,Zhen Gao
摘要
ABSTRACT Intrinsic chirality has garnered considerable interest due to its inherent spin–chiral interactions and exceptional capacity for optical field localization. Approaches to achieving optical chirality via bound states in the continuum (BICs) generally require breaking both in‐plane and out‐of‐plane symmetries simultaneously, which adds fabrication complexity and impedes the realization of concurrent chirality on both sides of a structure. Here, we experimentally demonstrate intrinsic planar chirality arising from intrinsic chiral BICs by concurrently breaking in‐plane and time‐reversal symmetries in a two‐dimensional self‐biased magneto‐optical photonic crystal, thereby obviating the need for any external magnetic field. Since the out‐of‐plane symmetry is preserved, the structure can support intrinsic chiral BICs on both sides at the Γ point. The resulting intrinsic chiral BIC achieves a theoretical radiation quality factor exceeding 10 7 and a circular dichroism value of up to 0.85. Moreover, we experimentally show that the chirality of these intrinsic chiral BICs can be reversibly switched by simply reversing the magnetization direction, with all structural parameters held constant. Our work establishes a general and efficient design paradigm for chiral photonic devices, with promising applications in biosensing and optical detection.
科研通智能强力驱动
Strongly Powered by AbleSci AI