以作者查詢圖書館館藏

、以作者查詢臺灣博碩士

、以作者查詢全國書目

、勘誤回報

、線上人數：15

、訪客IP：18.226.96.61

姓名	鄭民安(Ming-An Zheng)  查詢紙本館藏	畢業系所	電機工程學系
論文名稱	砷化銦鎵/砷化鋁銦單光子崩潰二極體陣列 之光學串擾模擬 (Simulation of Optical Crosstalk in InGaAs/InAlAs Single Photon Avalanche Diode Array)
相關論文	★ 應用自差分電路對具有不同擊穿電壓之多層累增層的砷化銦鎵/砷化銦鋁之單光子雪崩二極體性能影響 ★ 改變電荷層摻雜濃度之砷化銦鎵/砷化銦鋁單光子累增二極體的特性探討 ★ 具有分佈式布拉格反射結構的砷化銦鎵/砷化銦鋁單光子崩潰二極體的特性分析 ★ 在砷化銦鎵 /砷化鋁銦單光子崩潰二極體中崩潰閃光引致光學串擾之探討 ★ 改善載子傳輸之砷化銦鎵/砷化銦鋁平台式單光子崩潰二極體的設計與其特性 ★ 砷化銦鎵/磷化銦單光子雪崩型偵測器暗計數特性分析 ★ 砷化銦鎵/砷化銦鋁單光子崩潰二極體 元件製作及適當電荷層濃度模擬分析 ★ 應用於單光子雪崩二極體之氮化鉭薄膜電阻器的特性探討 ★ 砷化銦鎵/砷化銦鋁單光子崩潰二極體的設計與特性探討 ★ 砷化銦鎵/磷化銦單光子崩潰二極體暗與光特性分析 ★ 砷化銦鎵/磷化銦單光子崩潰二極體正弦波 閘控模式之暗與光特性分析 ★ 砷化銦鎵/砷化銦鋁平台式雙累增層單光子崩潰二極體的設計與其特性 ★ 考慮後段製程連線及佈局優化之積層型三維靜態隨機存取記憶體 ★ 鐵電場效電晶體記憶體考慮金屬功函數變異度之分析 ★ 蝕刻深度對平台式雙累增層砷化銦鎵/砷化銦鋁單光子崩潰二極體之影響 ★ 應用於非揮發性鐵電靜態隨機存取記憶體之變異容忍性召回操作
檔案	[Endnote RIS 格式]    [Bibtex 格式]    [相關文章]   [文章引用]   [完整記錄]   [館藏目錄]   [檢視]  [下載] 本電子論文使用權限為同意立即開放。 已達開放權限電子全文僅授權使用者為學術研究之目的，進行個人非營利性質之檢索、閱讀、列印。 請遵守中華民國著作權法之相關規定，切勿任意重製、散佈、改作、轉貼、播送，以免觸法。
摘要(中)	近紅外單光子崩潰二極體 (Single Photon Avalanche Photodiode, SPAD)的應用相當廣泛，包含生物螢光分析、電子產業的VLSI 電路、 軍事、商業上的量子加密和車用電子偵測系統等。其操作原理是利用 元件逆向偏壓於崩潰電壓之上，理論而言吸收單光子便能觸發衝擊游 離機制，產生無窮大之增益，因此能夠偵測極弱的光。 為了提高動態偵測範圍 (dynamic range)或實現成像相關之應用， 可將SPAD 元件製作成多像素陣列；陣列的設計目標是縮小SPAD 元 件之間的距離以提高偵測效率，減少光子損失。然而當元件間距微縮 時，因元件崩潰時產生的breakdown flash 將影響相鄰元件的操作，導 致鄰近元件發生不預期之崩潰，換言之，元件間距縮小將使光學串擾 的現象越趨嚴重；在此論文中，我們使用光學模擬軟體Rsoft 的 Fullwave 功能，將計算共振腔品質因子的方法延伸到模擬SPAD 元件 中的光學串擾，計算二維陣列中breakdown flash 傳遞至相鄰元件的能 量密度，並藉此方法計算在不同元件間距、金屬溝槽隔離、隔離深度 條件下，breakdown flash 對相鄰元件的影響，結果顯示能量密度與預 期趨勢相同，印證我們提出的方法可延伸模擬SPAD 陣列光學串擾之 現象。我們亦進一步討論共振腔結構對陣列中光學串擾的影響。
摘要(英)	Near infrared single photon avalanche diodes (SPAD) have many applications in various field, such as fluorescence lifetime imaging microscopy in life sciences, VLSI circuits in electronics industries, military and commercial quantum encryption, and automotive electronic detection systems. A SPAD is reversely biased above the breakdown voltage and the absorption of single photon can trigger impact ionization process, resulting infinite number of carriers. Therefore, it is capable of detecting faint light. In order to improve the dynamic range as well as to perform the imaging applications, a multi-pixel SPAD array is required. The array size and density increases for improving photon detection efficiency and reducing the losses of incoming photons. However, as the distance between each pixel is reduced, the breakdown flash generated by the avalanche carriers will couple to nearby SPADs in the array and induce unwanted avalanche events. In other words, the optical crosstalk will become more serious as shrinking the spacing between pixels. In this thesis, we use the simulation tool of Fullwave in Rsoft to study the optical crosstalk in SPADs by applying the method that is used to calculated the quality factor of an optical cavity. Based on the above method, we can calculate the energy density of breakdown flash propagation in a 2D array. The optical crosstalk can be well predicted under different conditions of pixel spacing, metal coated trench, and trench depth. We further discuss the optical crosstalk in the resonant cavity-enhanced SPAD structure.
關鍵字(中)	★ 單光子針測器 ★ 光學串擾	關鍵字(英)	★ single photon avalanche diodes ★ optical crosstalk
論文目次	目錄 摘要 ............................................................................................................. i Abstract ...................................................................................................... ii 致謝 ........................................................................................................... iii 目錄 ........................................................................................................... iv 圖目錄 ....................................................................................................... vi 第1 章 緒論............................................................................................... 1 1-1 前言 ............................................................................................. 1 1-1-1 光電倍增管 ...................................................................... 1 1-1-2 偵測波段與材料 .............................................................. 2 1-1-3 單光子元件與其陣列之應用 .......................................... 3 1-1-4 光學串擾於SPAD 陣列的影響 ...................................... 4 1-2 論文大綱 ..................................................................................... 7 第2 章 Rsoft 模擬軟體介紹 ..................................................................... 7 2-1 能量密度模擬方法說明 ............................................................. 8 2-1-1 Power/Total density ........................................................... 9 2-1-2 Q Factor ............................................................................. 9 2-2 FDTD 演算法 ............................................................................. 11 2-2-1 介紹 ................................................................................ 11 2-2-2 公式推導 ........................................................................ 11 2-2-3 穩定準則 ........................................................................ 14 v 2-2-4 吸收邊界 ........................................................................ 15 第3 章 砷化鎵銦單光子崩潰二極體 .................................................... 17 3-1 元件物理 ................................................................................... 17 3-1-1 崩潰二極體操作範圍 .................................................... 17 3-1-2 單光子崩潰二極體操作原理 ........................................ 19 3-2 崩潰機制 ................................................................................... 20 3-2-1 齊納崩潰(Zener breakdown) ......................................... 20 3-2-2 雪崩崩潰(Avalanche breakdown) ................................. 21 3-2-3 累增增益 ........................................................................ 22 3-3 Breakdown flash 物理 ................................................................ 23 第4 章 結構設計與模擬 ........................................................................ 24 4-1 元件結構設計 ........................................................................... 24 4-2 模擬 ........................................................................................... 29 4-2-1 DBR 對數選擇 ............................................................... 29 4-2-2 使共振波長靠近1550nm ............................................. 30 4-2-3 改變陣列設計條件 ........................................................ 32 第5 章 結論與未來展望 ........................................................................ 40 參考文獻 ................................................................................................... 41
參考文獻	參考文獻 [1] H. Bruining, ”Physics and Application of Secondary Electron Emission,” 1954. [2] J.P.R. D vid nd .H. T n. ”M teri l nsider ti ns f r Av l nche Ph t di des.” IEEE J. Sel. Top. Quant, vol.14,pp.998-1009, 2008. [3] H. Yang, G. Luo, P. Karnchanaphanurach, T. M. Louie, I. Rech, S. Cova, L. Xun, nd X. S. Xie, “Pr tein nf rm ti n l Dyn mics Probed by Single-M lecule Electr n Tr nsfer,” Science 302, 262–266, 2003. [4] F. Stell ri, A. T si, F. Z pp , nd S. v , “ MOS circuit testing vi time-res lved luminescence me surements nd simul ti ns,” IEEE Trans. Instrum. Meas. 53, 163–169, 2004. [5] K. J. G rd n, . Fern ndez, P. D. T wnsend, nd G. S. Buller, “A short wavelength GigaHertz clocked fiber-optic quantum key distributi n system,” IEEE J. Quantum Electron. 40, 900–908, 2004. [6] C.Mathas. ADAS takes greater control in 2015. Available: http://ww.edu.com/design/automotive/4437761/ADAS-takes-greatercontrol- in-2015. [7] Andrea L. Lacaita, Member, IEEE, Franco Zappa, Stefan0 Bigliardi, nd M nfred0 M nfredi, “On the bremsstrahlung origin of hot carrier induced ph t ns in silic n devices,” IEEE Trans. Electron. Devices 40, 577–582, 1993. [8] Roland H. Hail’Z, “Studies n ptic l c upling between silic n p-n juncti ns,” Solid–State Electronics 8, 417–425, 1965. [9] W. J. Kindt, H. W. v n Zeijl, nd S. Middelh ek, “Optic l r sst lk 42 in Geiger Mode Avalanche Photodiode Arrays: Modeling, Prevention nd Me surement,” IEEE, 17 October 2005. [10] Ivan Rech, Antonino Ingargiola, Roberto Spinelli, Ivan Labanca, Stefano Marangoni, Massimo Ghioni and Sergio Cova, “Optic l crosstalk in single photon avalanche diode arrays: a new complete m del, ” OSA, June 2008. [11] Niccolò Calandri, Mirko Sanzaro, Lorenzo Motta, Claudio Savoia, and Alberto Tosi, Member, “Optic l r sst lk in InG As/InP SPAD Array:Analysis and Reduction With FIB-Etched Trenches,” IEEE, 2016. [12] K. S. Yee, ”Numerical solution of initial boundary value problems involoving Maxwell′s equation in isotropic media,” IEEE Trans. Antennas and Propagat., vol. 14, no. 3, pp. 300-307, May 1966. [13] Andreas C. Cangellaris, Member, ”Numerical stability and numerical dispersion of a compact 2-D/FDTD method used for the dispersion analysis of waveguides”, IEEE microwave and guided wave Letters, vol. 3, no. 1, January 1993. [14] J. P. Berenger, ”A perfectly matched layer for free-space simulation in finite-difference computer codes,” Annals of Telecommunications, 1994. [15] Gerrit Mur, ” Absorbing Boundary Conditions for the Finite Difference Approximation of the Time Domain Electromagnetic Field Equations,” IEEE, 1981. [16] Zhiqiang Bi, Keli Wu, Chen Wu, and John Litva, ”A dispersive boundary condition for microstrip component analysis using the FD-TD method,” IEEE Trans. Antennas and Propagat., vol. MTT-40, 43 no. 4, pp. 774-777, Apr. 1992. [17] O. M. Ramahi, ”Complementary operators: A method to annihilate artificial reflections arising from the truncation of the computational domain in the solution of patial differential equations,” IEEE Trans. Antennas and Propagat., vol. 43, pp. 697-704, Jul. 1995. [18] Zachary S. Sacks, David M. Kingsland, Robert Lee, and Jin-Fa Lee, ”A perfectly matched anisotropic absorber for use as an absorbing boundary condition,” IEEE Trans Antennas and Propagat., vol. 43, pp. 1460-1463, Dec. 1995. [19] J. P. Berenger, ”A perfectly matched layer for the absorption of electromagnetic waves,” J. Computat. Phys., vol. 114, pp. 185-200, 1994. [20] G. F. D ll Bett , “Av l nche ph t di des in submicr n MOS technologies for high-sensitivity im ging”, Rijeka, InTech, 2011. [21] Brian F. Aull, Andrew H. Loomis, Douglas J. Young, Richard M. Heinrichs, Bradley J. Felton, Peter J. Daniels, and Deborah J. Landers, “Geiger-Mode Avalanche Photodiodes for ThreeDimensional Imaging, ”Lincoln Lab. Journal, vol. 13, 2002. [22] S. Kasapa, J. A. Rowlands, S. D. Baranovskii, and K. Tanioka, ”Lucky drift impact ionization in amorphous semiconductors,” J. Appl. Phys., vol. 96, 2004.A. G. CHYNOWETH AND K. G. MCKAY Bell Telephone Laboratories, Murray Hil/, Rem Jersey. ” Photon Emission from Avalanche Breakdown in Silicon, ” PHYSICAL REVIEW, 1956. [23] A. G. CHYNOWETH AND K. G. MCKAY Bell Telephone Laboratories, Murray Hil/, Rem Jersey. ” Photon Emission from 44 Avalanche Breakdown in Silicon, ” PHYSICAL REVIEW, 1956. [24] YICHENG SHI, JANET ZHENG JIE LIM, HOU SHUN POH, PENG KIAN TAN, PEIYU AMELIA TAN, ALEXANDER LING, AND CHRISTIAN KURTSIEFER, ”Breakdown flash at telecom wavelengths in InGaAs avalanche photodiodes, ”Journal, 2017. [25] Richard D. Younger, K. Alex McIntosh, Joseph W. Chludzinski, Douglas C. Oakley, Leonard J. Mahoney, Joseph E. Funk, Joseph P. Donnelly, and S. Verghese Lincoln Laboratory, ”Crosstalk Analysis of Integrated Geiger-mode Avalanche Photodiode Focal Plane Arrays, ” Proc. of SPIE, Vol. 7320, 2010. [26] Mahdi Zavvari, Kambiz Abedi and Mohammad Karimi. ”Design of resonant cavity structure for efficient high-temperature operation of single-photon avalanche photodiodes, ” OSA, 2014. [27] M. Selim lhiiia and Samuel Strite, ”Resonant cavity enhanced photonic devices, ”Journal of Applied Physics, 1995.
指導教授	李依珊(Yi-Shan Lee)	審核日期	2020-1-21
推文	facebook   plurk   twitter   funp   google   live   udn   HD   myshare   reddit   netvibes   friend   youpush   delicious   baidu
網路書籤	Google bookmarks   del.icio.us   hemidemi   myshare