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Photonic Band Gap Structures on Polymer Materials for Microstructure Waveguidesand High-Speed Interconnects

机译：用于微结构波导和高速互连的高分子材料上的光子带隙结构

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Physical Optics Corporation (POC) proposed a new concept of creating photonicband gaps on optical waveguides for the realization of low loss bands. These low loss bands are particularly useful for the realization of high density optical interconnection networks for multi-chip modules and other single-board high-speed functional circuits. In the Phase I program, POC focused on the structures that can be used to construct waveguide photonic band gap structures, namely 2-D and I-D PBG structures. The understanding of these structures and a theoretical study of their contributions to optical beam confinement have been achieved. We further examined their operational properties, including polarization dependence and material index differential requirements. Beam confinement conditions for a large range of off-axis beam angles have been identified between two 1-D PBG structures, which is the basis for the construction of low loss waveguide bands. This strong beam confinement for large angle off-axis beams is not achievable in conventional optical waveguides based on total internal reflection. The applications of the waveguide PBG structures include high density optical interconnect buses, waveguide filters, micro-ring tunable filters and lasers, switches, and integrated wavelength division multipliexers. (MM).

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作者
Wang, M.;
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年度 1995
页码
总页数 40
原文格式 PDF
正文语种 eng
中图分类工业技术;
关键词
Photonics; Optical waveguides; Circuit interconnections; Microstructure; Polymers; Semiconductors; Reflection; Optical switching; Multiplexing; Optical filters;

机译：光子学;光学波导;电路互连;微结构;聚合物;半导体;反射;光学开关;多路复用;光学滤波器;

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专利

1. Photonic band gap in different spatial structures of two-dimensional amorphous photonic materials [J] . Hang S., Meng X., Jin C., Laser Physics: An International Journal devoted to Theoretical and Experimental Laser Research and Application . 2003,第11期

机译：二维非晶态光子材料不同空间结构中的光子带隙
2. Coherent homogenization of periodic structures: Transformation from structurally periodic (photonic band gap) structures to optically uniform materials [J] . S. M. Sadeghi, W. Li Journal of Applied Physics . 2009,第10期

机译：周期性结构的相干均质化：从结构周期性（光子带隙）结构到光学均匀材料的转变
3. Unfolding the band structure of non-crystalline photonic band gap materials [J] . Samuel Tsitrin, Eric Paul Williamson, Timothy Amoah, Scientific reports. . 2015,第期

机译：展开非晶体光子带隙材料的带结构
4. Band structure and photonic band gap in comb-like structure asymmetric with left-handed materials [C] . Younes Errouas, Zakaria Tahri, Youssef Ben-Ali, International Conference on Intelligent Systems and Advanced Computing Sciences . 2019

机译：左手材料不对称的梳状结构中的能带结构和光子带隙
5. Preparation and use of photonic band gap structures to manipulate the optical properties of photoactive materials. [D] . Julian, Michael David. 2005

机译：光子带隙结构的制备和使用，以操纵光敏材料的光学性质。
6. Unfolding the band structure of non-crystalline photonic band gap materials [O] . Samuel Tsitrin, Eric Paul Williamson, Timothy Amoah, -1

机译：展现非晶态光子带隙材料的能带结构
7. Photonic band gaps in materials with triply periodic surfaces and related tubular structures [O] . Michielsen, K, Kole, JS 2003

机译：具有周期性周期表面和相关管状结构的材料中的光子带隙

Photonic Band Gap Structures on Polymer Materials for Microstructure Waveguidesand High-Speed Interconnects

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