通信用纳米光子器件和电路

Proceedings of the 3rd ACM International Conference on Nanoscale Computing and Communication Pub Date : 2016-09-28 DOI:10.1145/2967446.2967467

Y. Fainman, A. Grieco, G. Porter, Jordan A. Davis

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引用次数: 0

摘要

当前的光学技术成本高、体积大、排列脆弱，而且难以与电子系统集成，无论是在制造过程中，还是在传输和检索光学元件可以处理的大量数据方面。我们最近的工作强调直接在芯片上构建光学子系统，使用与周围电子设备相同的光刻工具。按照规则的模式排列，亚波长特征作为一种超材料，其光学特性由模式及其成分的密度和几何形状控制。我们还设计了硅的二阶非线性，并构建了复合金属-介电-半导体谐振增益几何结构，用于创建用于光学信息系统芯片级集成的新型纳米激光器。在下文中，我们描述了我们在数据中心光电路交换网络的集成空分多路复用(SDM)方面的最新工作。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Nanophotonic Devices and Circuits for Communications

The current optical technology is costly, bulky, fragile in their alignment, and difficult to integrate with electronic systems, both in terms of the fabrication process and in terms of delivery and retrieval of massive volumes of data that the optical elements can process. Our most recent work emphasizes the construction of optical subsystems directly onchip, with the same lithographic tools as the surrounding electronics. Arranged in a regular pattern, subwavelength features act as a metamaterial whose optical properties are controlled by the density and geometry of the pattern and its constituents. We also engineered second order nonlinearities in silicon and constructed composite metal-dielectric-semiconductor resonant gain geometries used to create a new type of nanolasers for chip-scale integration of optical information systems. In the following we describe our most recent work on integrated space-division multiplexing (SDM) for data center optical circuits switching networks.

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Proceedings of the 3rd ACM International Conference on Nanoscale Computing and Communication

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