Boundary Feedback Fiber Random Microcavity Laser Based on Disordered Cladding Structures
Hongyang Zhu,
Bingquan Zhao,
Zhi Liu,
Zhen He,
Lihong Dong,
Hongyu Gao,
Xiaoming Zhao
Affiliations
Hongyang Zhu
Tianjin Key Laboratory of Quantum Precision Measurement Technology, Tianjin Navigation and Instrument Institute, Tianjin 300131, China
Bingquan Zhao
College of Intelligent Systems Science and Engineering, Harbin Engineering University, Harbin 150006, China
Zhi Liu
Tianjin Key Laboratory of Quantum Precision Measurement Technology, Tianjin Navigation and Instrument Institute, Tianjin 300131, China
Zhen He
Fiber Optics Research Centre, School of Information and Communication Engineering, University of Electronic Science & Technology of China, Chengdu 611731, China
Lihong Dong
Tianjin Key Laboratory of Quantum Precision Measurement Technology, Tianjin Navigation and Instrument Institute, Tianjin 300131, China
Hongyu Gao
Tianjin Key Laboratory of Quantum Precision Measurement Technology, Tianjin Navigation and Instrument Institute, Tianjin 300131, China
Xiaoming Zhao
Tianjin Key Laboratory of Quantum Precision Measurement Technology, Tianjin Navigation and Instrument Institute, Tianjin 300131, China
The cavity form of complex microcavity lasers predominantly relies on disordered structures, whether found in nature or artificially prepared. These structures, characterized by disorder, facilitate random lasing through the feedback effect of the cavity boundary and the internal scattering medium via various mechanisms. In this paper, we report on a random fiber laser employing a disordered scattering cladding medium affixed to the inner cladding of a hollow-core fiber. The internal flowing liquid gain establishes a stable liquid-core waveguide environment, enabling long-term directional coupling output for random laser emission. Through theoretical analysis and experimental validation, we demonstrate that controlling the disorder at the cavity boundary allows liquid-core fiber random microcavities to exhibit random lasing output with different mechanisms. This provides a broad platform for in-depth research into the generation and control of complex microcavity lasers, as well as the detection of scattered matter within micro- and nanostructures.
