簡易檢索 / 詳目顯示

回結果列表
研究生: 謝政良
Cheng-Liang Hsieh
論文名稱: 以HSQ為犧牲層之Air-gap銅導線之大馬士革製程整合
Damascene Process for Air-gap Cu Interconnects Using Sacrificial layer HSQ
指導教授: 葉鳳生
Fon-Shan Huang
口試委員:
學位類別: 碩士
Master
系所名稱: 電機資訊學院 - 電子工程研究所
Institute of Electronics Engineering
論文出版年: 2006
畢業學年度: 94
語文別: 中文
論文頁數: 78
中文關鍵詞: 空氣腔室大馬士革結構漏電流崩潰電場銅研磨製程
外文關鍵詞: air-gap, damascene structure, leakage current, breakdown electric field, CMP
相關次數: 點閱:2下載:0
分享至:
查詢本校圖書館目錄 查詢臺灣博碩士論文知識加值系統 勘誤回報

    • 摘要

    本論文之重點在於整合SiNx capped Cu/Ta/SiO2 air-gap 銅導線damascene 結構,其中將利用電鍍銅、擴散阻障層Ta、犧牲層HSQ以及佈護層SiNx…等技術來完成銅導線結構。並討論air-gap damascene平行導線的電性特徵(漏電流、崩潰電場)。
    在犧牲層HSQ方面,利用旋轉塗佈(spin on)方法將HSQ(hydrogen silsesquioxane,precursor : Fox15)和MIBK以比例2:1塗佈在樣品上,發現在預烤3500C 3分鐘的條件下,將cage-network-like HSQ浸泡在BOE溶液內,HSQ可由SiO2與其界面間快速掀去,故為一個良好之犧牲層。
    在化學機械研磨(CMP)方面,定義銅平行導線width/space分別為0.5/0.5μm, 銅研磨漿料以Al2O3顆粒(0.05μm)、HNO3與citric Acid 調製而成,之後嚐試搭配不同正/背壓(D.P/B.P)= 5.0/4.0、4.0/3.0、3.0/2.0 psi來移除銅,最後以Levasil Silica 50CK 、H2O2 及H2O調製而成的Ta研磨漿料,配合D.P/B.P =5.0/2.0 psi來移除Ta膜,並以SEM觀察研磨後的銅導線,找出其最佳研磨條件。
    將所有製程技術,包括犧牲層HSQ、擴散阻障層Ta和有電極電鍍銅方法配合化學機械研磨製作出SiNx capped air-gap Cu damascene平行導線結構,在漏電流量測方面,量測不同溫度(室溫、50℃、100℃、150℃、180℃)條件之下平行導線的漏電流,並討論 SiNx capped air-gap Cu damascene平行導線結構的漏電機制,在不同溫度下(室溫、100℃、195℃)量測SiNx capped air-gap Cu damascene平行導線結構的崩潰電場,並由量測到電場強度與SEM照片討論平行導線結構發生崩潰的原因。

    Abstract

    The purpose of this study is to fabricate the SiNx capped Cu/Ta/SiO2 air-gap damascene structure. It included the integration of the sacrificial layer HSQ, diffusion barrier layer Ta, copper electroplating, and the passivation layer SiNx. The electric characteristic of the air-gap damascene structure was investigated, and discussed the leakage current and breakdown field.
    For the sacrificial layer, we spun HSQ with MIBK at ratio=2:1 on SiO2 substrate. It was found that with pre-bake temperature 350℃3min, HSQ was a good sacrificial layer. The cage-network-like HSQ can be removed by BOE solution easily from the interface with SiO2.
    For CMP, the Cu lines were defined with width/space = 0.5/0.5μm. The slurry mixed with Al2O3 particle (0.05μm)、 HNO3 and citric acid. The polishing down pressure /back pressure varied 5.0/4.0、4.0/3.0、3.0/2.0 psi to remove Cu film. The slurry for Ta is mixture of Levasil Silica 50CK、H2O2, and H2O. From the SEM pictures, the best CMP condition for the structure can be determined. The optimum D.P/B.P=5/2 psi is applied to remove Ta film.
    The SiNx capped Cu/Ta/SiO2 air-gap damascene structure with diffusion barrier layer Ta (150□), the sacrificial layer HSQ and capped layer SiNx (200□) was fabricated. The SiNx capped samples were studied by the I-V measurement. The leakage current measurement was done at different temperature(RT、50℃、100℃、150℃、180℃), and leakage current mechanism can be analyzed. The breakdown electric field was also measured at different temperature (RT、100℃、195℃) and analyzed. The SEM images were taken in order to correlate to the electrical breakdown measurements.

    目錄 第一章 緒論 ……………………………………………………………………. 1 第二章 犧牲層HSQ的性質 ………………………………… 4 2-1 犧牲層(sacrificial layer)HSQ的性質 ………………………………….. 4 2-2 HSQ在BOE溶液中的蝕刻速率 ……………………………………... 5 第三章 絕緣層漏電流機制 …………………………………………………… 6 3-1 絕緣層漏電流機制概述 ………………………………………………. 6 第四章 量測儀器 ……………………………………………………………… 9 4-1 四點探針 ………………………………………………………………. 9 4-2 α-step ………………………………………………………………….. 10 4-3 電流-電壓 (I –V) 曲線量測及分析 ………………………………..... 10 4-4 歐傑電子能譜 ………………………………………………………… 11 4-5 掃描式電子顯微鏡(SEM) ……………………………………………. 12 第五章 實驗 …………………………………………………………………14 5-1 化學機械研磨(CMP) …………………………………………….…. 14 5-1-1 Ta薄膜研磨速率樣品之製作 ……………………………...... 14 5-1-2a Cu薄膜研磨之最佳條件 ……………………………16 5-1-2b Cu薄膜研磨研磨速率 …………………………… 17 5-2 犧牲層HSQ …………………………………… …17 5-2-1 HSQ膜樣品之製作 ………………………………… 17 5-3 Air-gap 銅導線結構樣品製作 ………………… 18 5-4 漏電流量測 ……………………………………… 20 5-5 Air-gap 銅導線結構在不同溫度的崩潰電場之量測 20 第六章 實驗與量測結果 ……………………………………………………32 6-1 化學機械研磨 ……………………………………………………… 32 6-1-1 擴散阻障層Ta之研磨速率(R.R) …………………32 6-1-2 Cu之研磨速率(R.R) …………………………………………33 6-2 犧牲層HSQ ………………………………………………………34 6-2-1 犧牲層HSQ膜厚 …………………………………34 6-3 Air-gap 銅導線結構鑲嵌結構(Cu damascene structure) ………… 34 6-4 漏電流量測 ………………………………………………………36 6-4-1 G-line stepper 定義的air-gap 銅導線漏電流特徵…………….36 6-4-2 變溫條件之下平行導線的漏電流變化 (I-line defined) ….… 36 6-4-3 平行導線的漏電流機制分析 ………………………………… 37 6-4-3a 漏電流量測結果對Schottky emission的討論 ………....37 6-4-3b 漏電流量測結果對Frenkel-Poole emission的討論 ….. .39 6-5 崩潰電場之量測 …………………………………………………39 第七章 結論 …………………………………………………………………….74 參考文獻 ………………………………………………………………………….76

    參考文獻
    [1]Peter Singer, Semiconductor International, p.91. June 1998
    [2] K. Maex, M. R. Baklanov, D. Shamiryan, F. Iacopi, S. H. Brongersma,
    and Z. S. Yanovitskaya, “Low dielectric constant materials for
    microelectronics”, Journal of Applied Physics, vol. 93(11), p.8793-8841,
    2003
    [3] C. Lin, L. Clevenger, F. Schnabel, F. F. Jamin, and D. Dobuzinski,
    “Planarization of dual-damascene post-metal-CMP structures”, IITC,
    p.99-86, 1999
    [4] C. Y. Chang, S. M. Sze, “ULSI Technology”, McGraw-Hill, Chap. 8, 1996
    [5] J. M. Steigerwald, S. P. Murarka, and R. J. Gutmann, “Chemical Mechanical
    Planization of Microelectronic materials”, John Wiley & Sons, Chap. 1, 1997
    [6] B. S. Kang, S. M. Lee, J. S. Kwak, D. S Yoon, and H. K. Baik, “The
    effectiveness of Ta prepared by Ion-Assisted Deposition as a diffusion barrier
    between copper and silicon”, Journal of the Electrochemical Society, vol.
    144(5), p.1807-1812, 1997
    [7] Khin Maung Latt , Liu Rong , W.G.Zhu, Y.K.Lee, J.Materials
    Sci. ,37,1941-1949(2002)
    [8] W.H.Teh, Electronics Letters, 36(25),2105-2106(2000)

    [9] 陳忠賢, “銅/鉭基擴散障礙層與低介電係數材料之製程整合”,
    國立清華大學博士論文, 2003
    [10] L.G. Gosset, V. Arnal, C. Prindle, R. Hoofman, G. Verheijden,
    R. Daamen, L. Broussous, F. Fusalba, M. Assous, R. Chatterjee,
    J. Torres, D. Gravesteijn, and K.C. Yu, “General review of issues
    and perspectives for advanced copper interconnections using air
    gap as ultra-low K material”
    [11] Junji Noguchi, Kiyohiko Sato, Nobuhiro Konishi, Syouichi Uno,
    Takayuki Oshima, Kensuke Ishikawa, Hiroshi Ashihara, Tatsuyuki
    Saito, Maki Kubo, Tsuyoshi Tamaru, Youhei Yamada, Hideo Aoki,
    and Tsuyoshi Fujiwara, “Process and Reliability of Air-Gap Cu
    Interconnect Using 90-nm Node Technology”, IEEE Transactions on
    Electron Devices, vol. 52, p.352-359 , 2005
    [12] R.Daamen, G.J.A.M. Verheijden, P.H.L. Babcken, T.Vandeweyer, J.Michelon, V.Nguyen Hoang, R.J.O.M Hoofman, M.K. Gallagher,“Air Gap Integration for the 45nm Node and Beyond”IEEE 2005
    [13] 曾威鈞,Air-gap銅導線製程整合和漏電流傳導機制,清華大學碩
    士論文(2005)
    [14] C.C. Yang, C. Chen, and J. Mater. Chem., “The structures and
    properties of hydrogen silsesquioxane (HSQ) films produced
    by thermal curing”, vol. 12, p.1138-1141, 2002
    [15] S. M. Sze, “Physics of Semiconductor Devices”, 2nd edition, Wiley,
    1981
    [16] C. Hamann, H. Burghardt, and T. Frauenheim, “Electrical
    Conduction Mechanisms in Solids”, Deutscher Verlag der
    Wissenschaften, 1988

    無法下載圖示 全文公開日期 本全文未授權公開 (校內網路)
    全文公開日期 本全文未授權公開 (校外網路)

    QR CODE