2μm波段片上光子集成器件的研究进展(特邀)  被引量：3

作　　者：王希 刘英杰 张子萌 王嘉宁 姚勇 宋清海 徐科 Wang Xi;Liu Yingjie;Zhang Zimeng;Wang Jianing;Yao Yong;Song Qinghai;Xu Ke(Department of Electronic&Information Engineering,Harbin Institute of Technology,Shenzhen 518055,China;Department of Science,Harbin Institute of Technology,Shenzhen 518055,China)

机构地区：[1]哈尔滨工业大学(深圳)电子与信息工程学院,广东深圳518055 [2]哈尔滨工业大学(深圳)理学院,广东深圳518055

出　　处：《红外与激光工程》2022年第3期94-105,共12页Infrared and Laser Engineering

基　　金：国家自然科学基金(61875049,U21 A20454);深圳市基础研究学科布局项目(JCYJ20180507183418012)。

摘　　要：随着大数据业务的迅速发展,为应对持续增长的带宽需求,光纤通信窗口逐渐从传统C波段向C+L波段拓展。探索新波段也成为了光通信领域迫切需要解决的关键问题。位于近红外与中红外之间的2μm波段具有低传输损耗和宽增益谱范围等优势,有望成为下一个光纤通信和空间激光通信的窗口。在商用光电子器件尚不成熟的情况下,实验室条件下已实现单波100 Gbit/s光传输记录。与此同时,2μm波段功能性器件的研究也成为备受关注的热点。文中重点介绍了2μm波段硅光子器件的研究进展,以及基于III-V族、铌酸锂薄膜、氮化硅、硫系玻璃等其他材料的一系列功能性器件,最后对2μm波段片上光子集成器的发展前景进行了展望。Driven by the development in big data services, the conventional optical fiber communication window was shifting from C-band to C+L band to meet the continuously increasing demand for bandwidths. Exploiting new wavebands became a crucial problem within the optical communications community. The 2 μm spectral range between near-infrared and mid-infrared held advantages of low transmission loss and broad gain bandwidth,which made it a promising candidate for the next window of free space laser and optical fiber communications.Even though the commercialization of the 2 μm optoelectronic devices was at early stage, recorded single-lane100 Gbit/s transmission had been achieved in the laboratory. In the meantime, developing functional elements in this wavelength range was attracting extensive interests. In this paper, the recent advances of 2 μm silicon photonic device were introduced. Photonic integrated components on other platforms like III-V, thin-film lithium niobate, silicon nitride, and chalcogenide glass were also discussed. Finally, the 2 μm was envisioned on-chip photonic integrated devices.

关 键 词：2μm波段 集成光学 片上集成光子器件 光子集成 

分 类 号：TN256[电子电信—物理电子学]