孤子
物理
宽带
微波食品加热
光学
脉搏(音乐)
相位噪声
带宽(计算)
噪音(视频)
非线性光学
航程(航空)
模式锁定
光抽运
频率梳
激光器
光电子学
材料科学
带宽限制脉冲
相(物质)
光纤激光器
量子噪声
量子光学
脉冲持续时间
原子物理学
激光泵浦
超短脉冲
作者
Ziqi Wei,Daewon Suk,Changrui Liu,Changxi Yang,Hansuek Lee,Chengying Bao
摘要
Soliton mode locking in microresonators enables chip-scale generation of low-noise optical and microwave signals. Pulse pumped solitons offer a platform for broadband microcomb generation with stabilized repetition rates and for exploring soliton physics. In this Letter, we present a theoretical and experimental investigation of Kerr-induced phase noise quenching (KINQ) in pulse pumped solitons. We derive a model that quantifies the locking bandwidth between the soliton and the pump pulse and reveals the mechanism of KINQ. Experiments in a silica microresonator show up to ∼20 dB of phase noise suppression from the pump. The lowest noise is achieved by tuning the pump repetition rate to expand the soliton existence range and operating near, but not at, its upper boundary of this range. Our results establish a theory for solitons trapped by a nonuniform background and offer guidelines for attaining low-noise states in coherently pumped systems.
科研通智能强力驱动
Strongly Powered by AbleSci AI