文件名称:Electrical-Measurements-(1)
介绍说明--下载内容均来自于网络,请自行研究使用
Three-dimensionally periodic (3D) photonic crystals that operate in the optical frequency domain have become
a concrete reality – and evidence of full photonic bandgap behaviour has been demonstrated reasonably
convincingly. Techniques have been developed that make it possible to grow 3D photonic crystal structures over
large areas with sufficient perfection to be of interest for some areas of application. Understanding how 3D PhCs
can modify the emission of for example Cadmium Telluride (CdTe) semiconductor nano-dots with emission in
the visible can open new device possibilities. The key parameter in the modification of the emission is the extent
to which the PhC is infilled. By modifying the infilling procedure it is possible to limit the infill to several layers
of the PhC, thereby allowing the rest of the PhC to modify the emission
a concrete reality – and evidence of full photonic bandgap behaviour has been demonstrated reasonably
convincingly. Techniques have been developed that make it possible to grow 3D photonic crystal structures over
large areas with sufficient perfection to be of interest for some areas of application. Understanding how 3D PhCs
can modify the emission of for example Cadmium Telluride (CdTe) semiconductor nano-dots with emission in
the visible can open new device possibilities. The key parameter in the modification of the emission is the extent
to which the PhC is infilled. By modifying the infilling procedure it is possible to limit the infill to several layers
of the PhC, thereby allowing the rest of the PhC to modify the emission
(系统自动生成,下载前可以参看下载内容)
下载文件列表
Electrical-Measurements (1).pdf