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研究生: 韓維學
W.-H. Han
論文名稱: 一維金屬-介電質光子晶體能隙特性研究
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: 2010
畢業學年度: 98
語文別: 中文
論文頁數: 33
中文關鍵詞: 光子晶體金屬能帶結構無秩序一維光子能隙
論文種類: 學術論文
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  • 光子晶體最初是在1987年被Yablonovitch and John 兩人所分別提出。在近二十年內光子晶體在光電科技上具有重大地位。光子晶體是由不同的折射率層周期排列而成,此種排列方式使光子晶體具有與固態晶體相同的能帶結構,當其週期與所處理光波長相當時,所造成的強散射效應,便形成光子能隙。光子晶體有許多方面的應用,在一維上即為薄膜,可讓需要的波段反射,二維的可做為波導。
    在此論文中,我們使光子晶體中的各層厚度皆些微不同,即無秩序(Disorder)來觀察不同的光子能隙頻譜增寬效應。首先,我們使用Drude model 理論來討論在不同的頻率下,金屬的損耗項的變化。在金屬-介電質光子晶體(MDPC)與介電質-介電質光子晶體(DDPC)中,我們除了改變厚度Disorder的程度。第二部分。還改變不同的結構周期。

    Photonic crystals (PCs) introduced by Yablonovitch and John in 1987 are the periodical structure. Over the past two decades, researches in PCs have become an important role in modern optical and photonic science and technology. PCs have an important feature, i.e., the existence of the photonic band gaps (PBGs) in certain frequencies, which are produced due to the Bragg reflections in the periodic interfaces. The applications of PCs include, for examples, the optical reflector in one-dimensional PC and optical waveguide in two-dimensional PCs, and so on.
    In this thesis, in the first part, we use the Drude model to discuss the loss issue of metal at different frequencies. In the second part, we study the band gap enhancement in the disordered PCs. We shall consider the metal-dielectric and dielectric-dielectric PCs. By designing the disordered thicknesses in PCs, the enhancement in PBGs will be shown.

    Contents Abstract i Acknowledgement iii Contents iv Chapter 1 Introduction 1-1 HISTORY OF PHOTONIC CRYSTALS 1 1-2 INTRODUCTION OF PHOTONIC CRYSTAL 1 1-3 APPLICATIONS IN PC 2 1-4 INTRODUCE IN THIS THESES 2 1-5 THESES OVERVIEW 3 Chapter 2 Theoretical Methods 2-1 DYNAMICAL MATRIX 4 2-2 A SINGLE SLAB 6 2-3 MULTILAYER SYSTEM 9 2-4 TRANSMITTANCE AND REFLECTANCE 10 2-5 QUARTER-WAVE STACK 12 Chapter 3 Dispersion Relation for 1D MDPC 3-1 INTRODUCTION 14 3-2 BASIC EQUATIONS 14 3-3 NUMERICAL RESULTS AND DISCUSSION 15 3-4 CONCLUSION 17 Chapter 4 Using Disorder to Enhance Band Gap in a MDPC 4-1 INTRODUCTION 18 4-2 THEOREM 18 4-3 NUMERICAL RESULTS AND DISCUSSION 20 4-4 CONCLUSION 23 Chapter 5 Band Gap Extension in a Disordered Quarter-wave DDPC 5-1 INTRODUCTION 24 5-2 DISORDERED DDPC 24 5-3 NUMERICAL RESULTS AND DISCUSSION 27 5-4 CONCLUSION 32 Chapter 6 CONCLUSIONS 33 References 34

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