Parity-time symmetry enabled ultra-efficient nonlinear optical signal processing

IF 27.2 Q1 OPTICS eLight Pub Date : 2024-04-04 DOI:10.1186/s43593-024-00062-w
Chanju Kim, Xinda Lu, Deming Kong, Nuo Chen, Yuntian Chen, Leif Katsuo Oxenløwe, Kresten Yvind, Xinliang Zhang, Lan Yang, Minhao Pu, Jing Xu
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Abstract

Nonlinear optical signal processing (NOSP) has the potential to significantly improve the throughput, flexibility, and cost-efficiency of optical communication networks by exploiting the intrinsically ultrafast optical nonlinear wave mixing. It can support digital signal processing speeds of up to terabits per second, far exceeding the line rate of the electronic counterpart. In NOSP, high-intensity light fields are used to generate nonlinear optical responses, which can be used to process optical signals. Great efforts have been devoted to developing new materials and structures for NOSP. However, one of the challenges in implementing NOSP is the requirement of high-intensity light fields, which is difficult to generate and maintain. This has been a major roadblock to realize practical NOSP systems for high-speed, high-capacity optical communications. Here, we propose using a parity-time (PT) symmetric microresonator system to significantly enhance the light intensity and support high-speed operation by relieving the bandwidth-efficiency limit imposed on conventional single resonator systems. The design concept is the co-existence of a PT symmetry broken regime for a narrow-linewidth pump wave and near-exceptional point operation for broadband signal and idler waves. This enables us to achieve a new NOSP system with two orders of magnitude improvement in efficiency compared to a single resonator. With a highly nonlinear AlGaAs-on-Insulator platform, we demonstrate an NOSP at a data rate approaching 40 gigabits per second with a record low pump power of one milliwatt. These findings pave the way for the development of fully chip-scale NOSP devices with pump light sources integrated together, potentially leading to a wide range of applications in optical communication networks and classical or quantum computation. The combination of PT symmetry and NOSP may also open up opportunities for amplification, detection, and sensing, where response speed and efficiency are equally important.
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利用奇偶时对称性实现超高效非线性光学信号处理
非线性光信号处理(NOSP)通过利用固有的超快光非线性波混合,有可能显著提高光通信网络的吞吐量、灵活性和成本效益。它可以支持高达每秒太比特的数字信号处理速度,远远超过电子信号处理的线路速率。在 NOSP 中,高强度光场用于产生非线性光学响应,这些响应可用于处理光信号。人们一直致力于开发用于 NOSP 的新材料和新结构。然而,实现 NOSP 的挑战之一是需要高强度光场,而这种光场很难产生和维持。这一直是实现用于高速、大容量光通信的实用 NOSP 系统的主要障碍。在此,我们建议使用奇偶校验时间(PT)对称微谐振器系统,通过缓解传统单谐振器系统的带宽效率限制,显著增强光强度并支持高速运行。其设计理念是,窄线宽泵浦波的 PT 对称性被打破,而宽带信号波和惰波则近乎超常点工作。这使我们能够实现一种新型 NOSP 系统,与单谐振器相比,效率提高了两个数量级。利用高度非线性的 AlGaAs-on-Insulator 平台,我们展示了一个数据传输率接近每秒 40 千兆比特的 NOSP 系统,其泵浦功率低至创纪录的一毫瓦。这些发现为开发集成了泵浦光源的全芯片级 NOSP 器件铺平了道路,从而有可能在光通信网络、经典或量子计算领域实现广泛应用。PT 对称性和 NOSP 的结合还可能为放大、检测和传感带来机遇,因为在这些领域,响应速度和效率同样重要。
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30.40
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