以金屬與多層介電質組態為基礎之新型波導布拉格光柵; A Novel Metal/Multi-Insulator/Metal Waveguide Plasmonic Bragg Grating

Please use this identifier to cite or link to this item: http://ir.lib.ncu.edu.tw/handle/987654321/46457

Title:	以金屬與多層介電質組態為基礎之新型波導布拉格光柵;A Novel Metal/Multi-Insulator/Metal Waveguide Plasmonic Bragg Grating
Authors:	羅國垣;Guo-Yuan Luo
Contributors:	光電科學研究所
Keywords:	表面電漿子;布拉格光柵;plasmonics;Bragg Gratting;SPP
Date:	2011-03-24
Issue Date:	2011-06-04 15:54:15 (UTC+8)
Publisher:	國立中央大學
Abstract:	本論文探討新型結構之表面電漿波導布拉格光柵，將金屬與多層介電質組態取代傳統金屬與單層介電組態之電漿子波導，在高介電材料與金屬之間加入低折射率材料，可降低有效折射率之虛部，進而減少損耗。研究顯示增加低折射率材料區域之寬度可使有效折射率之實部、虛部下降；而增加高折射率材料區域寬度反而使有效折射率之實部上升、虛部下降。利用有限元素法為基礎之數值模擬設計布拉格波長為1310 nm 窄頻、1550 nm窄頻及1550 nm寬頻之波導布拉格光柵。1310 nm窄頻設計之布拉格光柵的禁帶半高全寬(full width at half maximum, FWHM)帶寬為15 nm，1550 nm窄頻及寬頻設計之布拉格光柵的禁帶半高全寬為2.9 nm及174 nm。操作波長在禁帶中，發現能量在布拉格光柵中形成渦流。操作波長在通帶中，布拉格光柵在矽與二氧化矽中能量會互相耦合交換。本論文亦分析製程誤差使布拉格光柵可能產生之傳輸特性變化。當波導結構週期長度或二氧化矽間隙寬度增加時，使布拉格波長紅移。相較於窄頻設計之布拉格光柵，寬頻設計之布拉格光柵，當其二氧化矽間隙寬度變化約±6 nm或當週期長度變化約±16 nm將使禁帶中某些波長之傳輸效率提升至10%；當變化幅度愈大，傳輸頻譜最後將分成兩個禁帶，因此寬頻設計之布拉格光柵所承受之製程容忍度遠小於窄頻設計。 A novel metal/multi-insulator/metal (MMIM) waveguide plasmonic Bragg grating is described in this thesis. The imaginary part of the mode index associated with an unperturbed MMIM waveguide can be decreased by inserting a low-index material in between the high-index core and metal region. It is shown that, as the width of the low-index region increases, the real and imaginary parts of the mode index decrease. On the other hand, as the width of the high- index region increases, the real part of the effective index increases but the imaginary part decreases. The design and analysis of the grating presented in this thesis are conducted using the finite-element-method-based numerical simulations. By optimizing the structure parameters, several design examples are obtained, including narrow-band/wide-band designs in the 1310-nm and 1550-nm communication windows. For the narrow-band cases, the full-width-at-half-maximum bandwidths are 15 nm and 2.9 nm for the 1310- and 1550-nm designs, respectively, while that of the 1550-nm wideband case is 174 nm. Time-average power vertexes are shown to occur in the stop band in particular for the narrow-band design examples. Moreover, power interchange exists between the silicon core and silica gap regions in the passband. The fabrication tolerance associated with the proposed Bragg grating is also studied. The Bragg wavelength exhibits a red shift if the period or silica gap width is larger than the designed value. For the wide-band design, fabrication errors in silica gap width of ±6 nm or in period of ±16 nm may raise the power transmission to about 10% in the stop band. An even larger error can finally cause the transmission spectrum to split into two stop bands. The fabrication tolerance associated with the wide-band design is found to be smaller than that in the narrow-band cases.
Appears in Collections:	[Graduate Institute of Optics and Photonics] Electronic Thesis & Dissertation

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