光隔离器
插入损耗
光学
传输(电信)
波导管
材料科学
光电子学
硅
硅光子学
透射系数
传输损耗
物理
光通信
集成光学
分离(微生物学)
光子集成电路
时域有限差分法
光开关
Q系数
光子学
非线性光学
电力传输
光学材料
慢光
光环行器
航程(航空)
克尔效应
共振(粒子物理)
调制(音乐)
光子晶体
纳米结构
作者
Junxian Shi,Shuai Li,Yuan Liu,Zhengqi Liu,Xianping Wang,Jing Chen,Xiaoshan Liu,Guiqiang Liu
出处
期刊:Optics Letters
[Optica Publishing Group]
日期:2025-12-17
卷期号:51 (2): 301-301
被引量:1
摘要
Nonreciprocal transport is indispensable for many modern optical devices. However, traditional nonreciprocal devices heavily depend on external bias. Achieving significant nonreciprocity in practice remains challenging. In this work, we propose a Kerr-nonlinearity-based design to achieve strong nonreciprocal transmission. By leveraging high- Q guided-mode resonances (GMRs) in a Si waveguide nanostructure decorated with periodic grooves, we demonstrate magnetic-free bidirectional nonreciprocal transmission and isolation. A large nonreciprocal intensity range (NRIR ≈ 3.7) is achieved through parameter tuning under the low pump intensity. Simultaneously, high-performance bidirectional isolation behaviors are realized including an isolation of 71.16 dB with 2.59 dB insertion loss for forward transmission and an isolation of 80.98 dB with 1.62 dB insertion loss for reverse transmission. This design offers a versatility for applications in optical communication, optical switches, and bidirectional nonreciprocal devices.
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