Photonic Crystal-Structures for THz Vacuum Electron Devices

Letizia R.; Mineo M.; Paoloni C.

首页> 外文期刊>Electron Devices, IEEE Transactions on >Photonic Crystal-Structures for THz Vacuum Electron Devices

【24h】

Photonic Crystal-Structures for THz Vacuum Electron Devices

机译：太赫兹真空电子器件的光子晶体结构

获取原文

获取原文并翻译 | 示例

开具论文收录证明 >>

页面导航

摘要
著录项
引文网络
相似文献
相关主题

摘要

The technology of photonic crystals (PhCs) is investigated here to improve the performance of THz vacuum electron devices. Compared with conventional metallic waveguides, the PhC arrangement alleviates typical issues in THz vacuum electron tubes, i.e. difficult vacuum pumping process and assembling, and improves the input/output coupling. A slow-wave structure (SWS) based on a corrugated waveguide assisted by PhC lateral walls and the efficient design of a PhC coupler for sheet-beam interaction devices are demonstrated. Based on the proposed technology, a backward-wave oscillator (BWO) is designed in this paper. Cold parameters of the novel PhC SWS as well as 3-D particle-in-cell simulations of the overall BWO are investigated, obtaining more than 70-mW-peak output power at 0.650 THz for beam voltage of 11 kV and beam current of 6 mA.

机译：本文研究了光子晶体（PhCs）技术，以提高THz真空电子器件的性能。与传统的金属波导相比，PhC装置减轻了太赫兹真空电子管中的典型问题，即困难的真空抽运过程和组装，并改善了输入/输出耦合。演示了一种基于波状波导的慢波结构（SWS），该波状波导由PhC侧壁辅助，并且设计了用于片束相互作用设备的PhC耦合器。基于所提出的技术，本文设计了一种反向波振荡器（BWO）。研究了新型PhC SWS的冷参数以及整个BWO的3-D粒子模拟，在束流电压为11 kV和束流电流为6时，在0.650 THz时获得了超过70 mW的峰值输出功率。嘛。

著录项

来源
《Electron Devices, IEEE Transactions on》 |2015年第1期|178-183|共6页
作者
Letizia R.; Mineo M.; Paoloni C.;
展开▼
作者单位

Department of Engineering, Lancaster University, Lancaster, U.K.;

展开▼
收录信息美国《科学引文索引》(SCI);美国《工程索引》(EI);
原文格式 PDF
正文语种 eng
中图分类
关键词
Couplers; Couplings; Cutoff frequency; Electromagnetic waveguides; Electron devices; Photonic band gap; Power generation; Backward-wave oscillator (BWO); THz; corrugated waveguide; photonic bandgap (PBG); photonic crystal (PhC); vacuum electron devices; vacuum electron devices.;

机译：耦合器;耦合;截止频率;电磁波导管;电子器件;光子带隙;发电;后向波振荡器（BWO）;太赫兹;波纹波导;光子带隙（PBG）;光子晶体（PhC）;真空电子器件;真空电子设备。;

相似文献

外文文献
中文文献
专利

1. THz Communications using Photonics and Electronic Devices: the Race to Data-Rate [J] . Ducournau Guillaume, Szriftgiser Pascal, Pavanello Fabio, Journal of Infrared, Millimeter and Terahertz Waves . 2015,第2期

机译：使用光子学和电子设备的太赫兹通信：争夺数据速率
2. Thermomechanical Fatigue in Sub-THz Vacuum Electron Devices [J] . Diana Gamzina, Bahram Ravani Electron Devices, IEEE Transactions on . 2016,第12期

机译：次太赫兹真空电子器件中的热机械疲劳
3. Slow-Wave Characteristics of a Frame-Rod Structure Based on Micro-Fabricated Technology for THz Vacuum Electron Devices [J] . Fu Chengfang, Zhao Bo, Yang Yudong, Journal of Infrared, Millimeter and Terahertz Waves . 2016,第11期

机译：基于微制造技术的太赫兹真空电子器件框架杆结构的慢波特性
4. Photonic band gap corrugated slow wave structure for THz sheet-beam vacuum electron devices [C] . Rosa Letizia, Mauro Mineo, Claudio Paoloni IEEE International Vacuum Electronics Conference . 2016

机译：太赫兹薄板真空电子器件的光子带隙波纹慢波结构
5. Electronic and photonic devices: Experimental investigations of hydrogenated amorphous silicon substrate n(+)/i/p(+) solar cell and fundamental properties of quantum wells with cylindrical geometry and applications to electronics and photonics [D] . Ping, Er-Xuan 1995

机译：电子和光子器件：氢化非晶硅衬底n（+）/ i / p（+）太阳能电池的实验研究以及具有圆柱几何形状的量子阱的基本特性及其在电子和光子学中的应用
6. Silk‐Based Diffractive Optics: Photoinduced Tunable and Reconfigurable Electronic and Photonic Devices Using a Silk‐Based Diffractive Optics Platform (Adv. Sci. 14/2020) [O] . Xiaoqing Cai, Zhitao Zhou, Tiger H. Tao 2020

机译：基于丝绸的衍射光学器件：使用基于丝绸的衍射光学平台进行光致可调和可重构电子和光子器件（Adv。Sci。14/2020）
7. Photonic band gap corrugated slow wave structure for THz sheet-beam vacuum electron devices [O] . Letizia R, Mineo M, Paoloni C 2016

机译：太赫兹薄板真空电子器件的光子带隙波纹慢波结构
8. Miniature Electron Sources for Tomorrow's Vacuum THz Devices (MiPRI) [R] . Carmel, Y. , Nusinovich, G. , Rodgers, J. , 2006

机译：明天真空THz器件的微型电子源（mipRI）

Photonic Crystal-Structures for THz Vacuum Electron Devices

摘要

著录项

引文网络

相似文献

相关主题

期刊订阅