(Peer-Reviewed) Non-volatile reconfigurable planar lightwave circuit splitter enabled by laser-directed Sb2S3 phase transitions
Shixin Gao 高仕鑫 ¹, Tun Cao 曹暾 ¹, Haonan Ren 任浩楠 ¹, Jingzhe Pang 庞景哲 ¹, Ran Chen 陈燃 ¹, Yang Ren 任杨 ³, Zhenqing Zhao 赵真清 ⁴, Xiaoming Chen 陈晓明 ¹, Dongming Guo 郭东明 ²
¹ School of Optoelectronic Engineering and Instrumentation Science, Dalian University of Technology, Dalian 116024, China
中国 大连 大连理工大学光电工程与仪器科学学院
² Key Laboratory for Precision and Non-traditional Machining Technology of Ministry of Education, Dalian University of Technology, Dalian 116024, China
中国 大连 大连理工大学精密与特种加工教育部重点实验室
³ Huawei Technologies, B & P Laboratory, Shenzhen 518000, China
中国 深圳 华为技术有限公司,B & P实验室
⁴ Huawei Technologies, Optical R & D Dept. Dongguan 523808, China
中国 东莞 华为技术有限公司,光学研发部
Opto-Electronic Technology
, 2025-07-18
Abstract
Planar lightwave circuit (PLC) splitters have long been foundational components in passive optical communication networks, achieving commercial success since the 1990s. However, their inherent fixed splitting ratios impose significant limitations on capacity expansion, often requiring physical replacement and causing service disruptions.
Thermally tunable optical splitters address this challenge by enabling adjustable splitting ratios, but their operation is contingent upon a continuous power supply and complex driving systems. In this work, we present a novel, non-volatile tunable PLC platform based on Sb2S3 phase-change materials. The proposed device, which incorporates a Mach-Zehnder interferometer (MZI) optical switch structure, offers tunable splitting ratios via laser-direct writing or ohmic heating, providing flexible reconfiguration capabilities.
Experimental results demonstrate non-volatile power splitting ranging from 50∶50 to 20∶80, with a modest increase of approximately 1 dB in additional loss. This work highlights the potential of the proposed platform for low-power, high-efficiency, and reconfigurable photonic networks.
Flicker minimization in power-saving displays enabled by measurement of difference in flexoelectric coefficients and displacement-current in positive dielectric anisotropy liquid crystals
Junho Jung, HaYoung Jung, GyuRi Choi, HanByeol Park, Sun-Mi Park, Ki-Sun Kwon, Heui-Seok Jin, Dong-Jin Lee, Hoon Jeong, JeongKi Park, Byeong Koo Kim, Seung Hee Lee, MinSu Kim
Opto-Electronic Advances
2025-09-25
Dual-frequency angular-multiplexed fringe projection profilometry with deep learning: breaking hardware limits for ultra-high-speed 3D imaging
Wenwu Chen, Yifan Liu, Shijie Feng, Wei Yin, Jiaming Qian, Yixuan Li, Hang Zhang, Maciej Trusiak, Malgorzata Kujawinska, Qian Chen, Chao Zuo
Opto-Electronic Advances
2025-09-25
