侧墙倾斜的水平半导体/空气分布布喇格反射器的设计

王海龙; 秦文华

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侧墙倾斜的水平半导体/空气分布布喇格反射器的设计

研究论文 | 更新时间：2020-08-11

- 侧墙倾斜的水平半导体/空气分布布喇格反射器的设计
- Design for Horizontal Semiconductor-Air Distributed Bragg Reflectors with the Tilt of Vertical Sidewall
- 发光学报 2007年28卷第2期页码：225-230
- 作者机构：
  
  曲阜师范大学物理工程学院, 山东, 曲阜,273165
- 作者简介：
- 基金信息：
  
  曲阜师范大学博士科研启动基金资助项目(XJ0622)()
- DOI：
  中图分类号： O472.3
- 收稿日期：2006-07-20，
  
  修回日期：2006-11-17，
  
  纸质出版日期：2007-03-20
- 稿件说明：
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王海龙, 秦文华. 侧墙倾斜的水平半导体/空气分布布喇格反射器的设计[J]. 发光学报, 2007,28(2): 225-230

WANG Hai-long, QIN Wen-hua. Design for Horizontal Semiconductor-Air Distributed Bragg Reflectors with the Tilt of Vertical Sidewall[J]. Chinese Journal of Luminescence, 2007,28(2): 225-230
王海龙, 秦文华. 侧墙倾斜的水平半导体/空气分布布喇格反射器的设计[J]. 发光学报, 2007,28(2): 225-230 DOI：

WANG Hai-long, QIN Wen-hua. Design for Horizontal Semiconductor-Air Distributed Bragg Reflectors with the Tilt of Vertical Sidewall[J]. Chinese Journal of Luminescence, 2007,28(2): 225-230 DOI：

摘要

时域有限差分(FDTD)法计算表明

在常规的水平半导体/空气分布布喇格反射器(DBR)设计中为了得到高反射率

DBR中侧墙与衬底垂直非常重要。对于GaN基材料DBR侧墙如果有3°的倾斜

反射率将下降到30%左右

然而在实验上很难得到侧墙与衬底垂直的GaN基DBR结构。考虑到侧墙倾斜问题我们提出了新的DBR设计方法

采用这种方法即使DBR侧墙有较大的倾斜也可以得到高的反射率。设计的关键是在侧墙倾斜的情况下保持每个DBR周期光程差与垂直情况下一致

根据光的干涉原理我们给出了详细的解释。

Abstract

It has been shown that high reflectivity mirrors can be formed by deeply etched semiconductor/air distributed Bragg reflectors (DBRs). The DBR structures are almost identical to multilayers of semiconductor and air. Current etching technologies can produce deep uniform etches in semiconductors. The finite dif-ference time domain (FDTD) method directly solves Maxwell’s equation in time. It is remarkably robust

providing accurate modeling for various electromagnetic wave interaction and field problem. Rapid advances in computer technology make the FDTD method more and more attractive every day. In this work we use the FDTD method in two dimensions to study a GaN-based semiconductor/air DBR structure. We take account of the TE mode and considering the geometry to be invariant in the lateral direction perpendicular to the light propagation. The spectral reflectivity is calculated by comparing the spectral content of the incident and reflected pulse. FDTD simulations show that vertical sidewall tilt is a crucial concern for obtaining a high-reflectivity DBR in a conventional design. The middle widths of semiconductor should increase to obtain the high reflec-tivity with the sidewall angle decreasing. To obtain high reflectivity at designed wavelength

the difference of optical path for one DBR pitch should keep constant. When the sidewall tilted

the difference of optical paths decrease. This phenomena can be explained using the knowledge of interference. To increase the optical paths difference

the air space and/or semiconductor width should be increased. The increase of air space will also increase the diffractive spreading loss

which arises because modal confinement is limited to the semiconductor region. In the air gaps

light is not confined and the refractive index of the air is much lower than that of the semiconductor

the optical field diverges quickly upon reaching the semiconductor-air interface. So

the semiconductor width should be increased to increase the optical width. Thus

high reflectivity can be reached with the proper design even with a large vertical sidewall tilt. Experimentally

it is difficult to etch vertical sidewalls of GaN-based materials

so the new design to overcome this difficulty is very meaningful.

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