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研究生: 謝亞璋
Ya-Chang Hsieh
論文名稱: 一維半導體光子晶體光學性質之研究
Optical Properties in One-dimensional Semiconductor Photonic Crystal
指導教授: 吳謙讓
Wu, Chien-Jang
學位類別: 碩士
Master
系所名稱: 光電工程研究所
Graduate Institute of Electro-Optical Engineering
論文出版年: 2011
畢業學年度: 99
語文別: 中文
論文頁數: 50
中文關鍵詞:
英文關鍵詞: photonic
論文種類: 學術論文
相關次數: 點閱:128下載:0
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    • Photonic crystals (PCs), artificial periodic structures, have attracted much attention over the past two decades. Conventional dielectric-dielectric PCs have been greatly studied in the literature. In this thesis, we have studied the optical properties in semiconductor-dielectric photonic crystals (SDPCs). There are three topics. The first one is to study the near-infrared photonic band structure in a doped SDPC. By varying the doping concentration in n-Si, tunable properties in such a PC have been investigated in detail. The effect of filling factor on the PBG is also reported.
    The second part is to study the absorption issue in an SDPC. With the difference in the refractive indices in the constituent layers and the existence of imaginary part of the index, enhancement in the absorption in the band edges is clearly shown. This enhancement is an requirement in the LED application.
    The third part is to study the thermally tunable photonic band structure and omnidirectional band gap. We use the intrinsic semiconductor InSb as one of the constituent in our binary PC. With the strongly temperature-dependent permittivity of InSb, the tunability in the photonic band structure and the omnidirectional gap is numerically investigated.

    Photonic crystals (PCs), artificial periodic structures, have attracted much attention over the past two decades. Conventional dielectric-dielectric PCs have been greatly studied in the literature. In this thesis, we have studied the optical properties in semiconductor-dielectric photonic crystals (SDPCs). There are three topics. The first one is to study the near-infrared photonic band structure in a doped SDPC. By varying the doping concentration in n-Si, tunable properties in such a PC have been investigated in detail. The effect of filling factor on the PBG is also reported.
    The second part is to study the absorption issue in an SDPC. With the difference in the refractive indices in the constituent layers and the existence of imaginary part of the index, enhancement in the absorption in the band edges is clearly shown. This enhancement is an requirement in the LED application.
    The third part is to study the thermally tunable photonic band structure and omnidirectional band gap. We use the intrinsic semiconductor InSb as one of the constituent in our binary PC. With the strongly temperature-dependent permittivity of InSb, the tunability in the photonic band structure and the omnidirectional gap is numerically investigated.

    Abstract i Acknowledgement ii Contents iii Chapter 1 Introduction 1-1 Literature Review 1 1-2 Motivations and Applications of PCs 2 1-3 ThesisOverview 3 Chapter 2 Theoretical Methods 2-1 Transfer Matrix Method (TMM) 4 2-2 Dynamical Matrix of a Medium 4 ----A Single-Boundary Problem 2-3 A Single Slab---Two-Boundary Problem 7 2-4 Matrix Formulation for Multilayer System 9 2-5 Transmittance and reflectance Chapter 3 Tunable PBG For A Doped Semiconductor PhotonicCrystal In Near Infrared Region 3-1 Introduction # 3-2 Basic equations # 3-3 Numerical results and discussion # 3-4 Conclusion # Chapter 4 Spectral Selectivity of Photonic Crystal InfraredPhotodetectors 4-1 Introduction # 4-2 Basic equations # 4-3 Numerical results and discussion # 4-4 Conclusion# Chapter 5 Thermally tunable and omnidirectional terahertz PBGin the 1-D PC containing semiconductor InSb 4-1 Introduction # 4-2 Basic equations # 4-3 Numerical results and discussion # 4-4 Conclusion # Chapter 6 Conclusions References #

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