簡易檢索 / 詳目顯示

研究生: 黃子祐
Huang, Zi-You
論文名稱: 無摻雜氧化鉿鐵電電容器和電晶體元件電性可靠度研究
Electrical Reliability Investigative of Dopant-Free Hafnium Oxide Metal-Ferroelectric-Metal Capacitor and Field-Effect Transistor
指導教授: 鄭淳護
Cheng, Chun-Hu
學位類別: 碩士
Master
系所名稱: 機電工程學系
Department of Mechatronic Engineering
論文出版年: 2020
畢業學年度: 108
語文別: 中文
論文頁數: 87
中文關鍵詞: 無摻雜二氧化鉿厚度效應金屬應力氮電漿
英文關鍵詞: Dopant-free HfO2, Thickness effect, Metal stress, Nitrogen-plasma
DOI URL: http://doi.org/10.6345/NTNU202001112
論文種類: 學術論文
相關次數: 點閱:120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
  • 隨著物聯網(Internet of Things)、車聯網(Internet of Vehicles)、人工智慧(Artificial Intelligence)及大數據(Big data)的蓬勃發展下,對於電子元件的需求與日俱增隨著元件不斷的微縮,在晶片單位面積上的元件數量隨之增加,總功率消耗有增加的趨勢,因此克服功率消耗成為重要的議題。藉由鐵電材料中的負電容效應,可以使傳統電晶體之次臨界擺幅(Subthreshold Swing, SS)低於60 mV/decade,因而進一步降低器件的功率消耗。傳統的鐵電材料像是鋯鈦酸鉛(lead zirconate titanate , PZT) 和鉭酸鍶鉍(strontium bismuth tantalite, SBT)等,有著難以微縮以及環境污染的問題。
    且近年來發現二氧化鉿材料能透過摻雜和金屬閘極的機械應力誘發鐵電特性,因此引起研究者的關注。再加上科技的走向,電子元件逐漸朝向尺寸微縮、低功率消耗和高速等趨勢發展,其中以鐵電特性為架構的鐵電隨機存取記憶體及負電容場效電晶體漸漸受到重視,然而高濃度摻雜鋯會使得元件漏電流的增加,而摻雜鋁會使得元件微縮時摻雜比例不易調控,故無摻雜氧化鉿逐漸受到重視且具研究價值。
    文獻中所示,無摻雜二氧化鉿薄膜可以透過厚度微縮及閘極應力誘發二氧化鉿材料結晶相轉變進而增強鐵電極化特性,本研究將10奈米的二氧化鉿薄膜微縮至7奈米,利用厚度效應來達到增強鐵電特性。厚度微縮雖然可以增強鐵電及化特性,但同時增加漏電流,為了改善漏電流的缺點本研究將二氧化鉿薄膜表面進行氮電漿處理。藉由氮電漿修補薄膜表面缺陷進而降低漏電流及改善元件可靠度,可靠度分析發現經過氮電漿修補後陷阱能障從0.453 eV改善至0.474 eV,將薄膜用於鐵電電晶體發現,經過氮電漿處理後臨界電壓從0.955 V偏移至1.65 V,缺陷視窗縮減0.25 V。此研究結果有助於將無摻雜二氧化鉿薄膜整合於記憶體。

    With the rapid development of Internet of things, Internet of vehicles, artificial intelligence and big data, the demand for electronic components is increasing day by day. With the continuous miniaturization of components, the number of components per chip area increases, and the total power consumption tends to increase. Therefore, overcoming power consumption has become an important topic. Because of the negative capacitance effect within ferroelectric materials, the subthreshold swing (SS) of traditional transistors can be lowered than 60 mV / decade, which can reduce the power consumption of the devices. Traditional ferroelectric materials, such as lead zirconate titanate, PZT and strontium bismuth tantalite, SBT and so on, suffer the process problems on miniaturization and environmental pollution. Therefore, dopant-free HfO2 with ferroelectricity as ferroelectric material for ferro device fabrication, which can effectively overcome the issues of element miniaturization and environmental pollution.
    In recent years, it has been found that HfO2 can induce ferroelectric properties through doping and the mechanical stress of metal gate, which has attracted the attention of researchers. In addition, with the development of science and technology, electronic components are gradually developing towards the trend of miniaturization, low power consumption and high speed. Among them, the low power technologies development of ferroelectric random access memory and “negative capacitance” logic transistor are widely investigated by Globe research groups. However, the common issues such as dopant diffusion (Zr), narrow doping tuning window, poor interface thermal stability, still need to be comprehensively studied.
    It has been shown in the literature that undoped HfO2 thin films can enhance the ferroelectric polarization properties by thickness reduction and gate stress induced crystal phase transformation. In this study, the thickness scaling strategy was used to enhance the ferroelectric properties of HfO2 thin films by reducing the thickness from 10 nm to 7 nm. Although the thickness reduction can enhance the ferroelectric and property, it also increases the magnitude of leakage current. In order to improve the leakage current, the surface passivation of hafnium dioxide film was treated by nitrogen plasma. We can find that the trap energy barrier of dopant-free HfO2 was improved from 0.453 eV to 0.474 eV after nitrogen passivation. The threshold voltage was shifted from 0.955 V to 1.65 V and the trap window was reduced by 0.25 V. The experimental results demonstrate that the ferroelectricity of dopant-free HfO2 can be improved by both thickness scaling strategy and remote nitrogen plasmas passivation, which can be beneficial for the integration on ferroelectric memory and negative capacitance transistor technologies.

    第一章 緒論 1 1.1 鐵電材料特性 1 1.2 負電容-場效電晶體(NC-FET) 3 1.3 基於二氧化鉿之鐵電材料 6 1.4 研究動機與目的 9 第二章 文獻回顧 10 2.1 二氧化鉿薄膜的相轉變 10 2.2 二氧化鉿摻雜鋁誘導相轉變 11 2.3 二氧化鉿摻雜鋯誘導相轉變 13 2.4 金屬閘極應變誘導相轉變 15 2.5 無摻雜二氧化鉿厚度微縮誘導相轉變 19 2.6 氮電漿改善電容器界面品質 21 第三章 實驗步驟 23 3.1 N型鐵電電晶體之實驗流程 23 3.2 金屬-鐵電-金屬(MFM)鐵電電容之實驗流程 28 3.3 量測儀器與分析方式 29 第四章 結果與討論 33 4.1 金屬-鐵電-金屬(MFM)二氧化鉿鐵電電容器之電性分析 33 4.1.1 二氧化鉿薄膜之厚度效應 33 4.1.2 二氧化鉿薄膜之應力效應 36 4.1.3 二氧化鉿薄膜經氮電漿修補改善介面品質 40 4.1.4 二氧化鉿薄膜經氮電漿處理與 PMA 溫度之探討 43 4.1.5 二氧化鉿薄膜經氮電漿處理對於介電係數之影響 48 4.2 金屬-鐵電-金屬(MFM)二氧化鉿鐵電電容器之可靠度分析 49 4.2.1 與時間相關之介電層崩潰分析(TDDB) 50 4.3 無摻雜二氧化鉿薄膜整合於鐵電場效電晶體(FeFET) 77 第五章 結論 83 參考文獻 85

    [1]C. Ahn, K. Rabe, and J.-M. Triscone, "Ferroelectricity at the nanoscale: local polarization in oxide thin films and heterostructures," Science, vol. 303, no. 5657, pp. 488-491, 2004.
    [2]S. Salahuddin and S. Datta, "Use of negative capacitance to provide voltage amplification for low power nanoscale devices," Nano letters, vol. 8, no. 2, pp. 405-410, 2008.
    [3]K. Jang, T. Saraya, M. Kobayashi, and T. Hiramoto, "Ion/Ioff ratio enhancement and scalability of gate-all-around nanowire negative-capacitance FET with ferroelectric HfO2," Solid-State Electronics, vol. 136, pp. 60-67, 2017.
    [4]C.-H. Cheng, C.-C. Fan, C.-Y. Tu, H.-H. Hsu, and C.-Y. Chang, "Implementation of dopant-free hafnium oxide negative capacitance field-effect transistor," IEEE Transactions on Electron Devices, vol. 66, no. 1, pp. 825-828, 2018.
    [5]E. Yurchuk et al., "Impact of scaling on the performance of HfO2-based ferroelectric field effect transistors," Ieee Transactions on Electron Devices, vol. 61, no. 11, pp. 3699-3706, 2014.
    [6]S. Martin, N. Baboux, D. Albertini, and B. Gautier, "A new technique based on current measurement for nanoscale ferroelectricity assessment: nano-positive up negative down," Review of Scientific Instruments, vol. 88, no. 2, p. 023901, 2017.
    [7]W. C. Yap, H. Jiang, J. Liu, Q. Xia, and W. Zhu, "Ferroelectric transistors with monolayer molybdenum disulfide and ultra-thin aluminum-doped hafnium oxide," Applied Physics Letters, vol. 111, no. 1, p. 013103, 2017.
    [8]E. Yurchuk et al., "Impact of scaling on the performance of HfO2-based ferroelectric field effect transistors," vol. 61, no. 11, pp. 3699-3706, 2014.
    [9]M. H. Park et al., "A comprehensive study on the structural evolution of HfO2 thin films doped with various dopants," Journal of Materials Chemistry C, vol. 5, no. 19, pp. 4677-4690, 2017.
    [10]S. Mueller et al., "Incipient ferroelectricity in Al‐doped HfO2 thin films," Advanced Functional Materials, vol. 22, no. 11, pp. 2412-2417, 2012.
    [11] J. Muller et al., "Ferroelectricity in simple binary ZrO2 and HfO2," Nano letters, vol. 12, no. 8, pp. 4318-4323, 2012.
    [12]T. Böscke, J. Müller, D. Bräuhaus, U. Schröder, and U. Böttger, "Ferroelectricity in hafnium oxide: CMOS compatible ferroelectric field effect transistors," in 2011 International Electron Devices Meeting, 2011, pp. 24.5. 1-24.5. 4: IEEE.
    [13]C.-C. Fan, C.-H. Cheng, Y.-R. Chen, C. Liu, and C.-Y. Chang, "Energy-efficient HfAlOx NCFET: using gate strain and defect passivation to realize nearly hysteresis-free sub-25mV/dec switch with ultralow leakage," in 2017 IEEE International Electron Devices Meeting (IEDM), 2017, pp. 23.2. 1-23.2. 4: IEEE.
    [14]P. Polakowski and J. Müller, "Ferroelectricity in undoped hafnium oxide," Applied Physics Letters, vol. 106, no. 23, p. 232905, 2015.
    [15]C. Wang et al., "Improved performance of Au nanocrystal nonvolatile memory by N2-plasma treatment on HfO2 blocking layer," Chinese Physics B, vol. 27, no. 6, p. 067303, 2018.
    [16]K.-J. Choi, J.-H. Kim, and S.-G. Yoon, "Plasma nitration of HfO2 gate dielectric in nitrogen ambient for improvement of TaN/HfO2/Si performance," Electrochemical and Solid State Letters, vol. 7, no. 10, p. F59, 2004.
    [17]N. Azizi and P. Yiannacouras, "Gate oxide breakdown," Lecture Notes, Reliability of Intergrated Circuits, 2003.
    [18]C.-L. Lin, M.-Y. Chou, J.-J. Hong, T.-K. Kang, S.-C. Wu, and P.-C. Juan, "Comparison of breakdown mechanism of HfO2 and HfSiOx high-k gate dielectrics with N2 RTA treatment on TDDB constant voltage stress," in 2009 16th IEEE International Symposium on the Physical and Failure Analysis of Integrated Circuits, 2009, pp. 163-168: IEEE.
    [19]M. C. Gust, L. A. Momoda, N. D. Evans, and M. L. Mecartney, "Crystallization of Sol–Gel‐Derived Barium Strontium Titanate Thin Films," Journal of the American Ceramic Society, vol. 84, no. 5, pp. 1087-1092, 2001.
    [20]Y.-C. Chiu, C.-H. Cheng, G.-L. Liou, and C.-Y. Chang, "Energy-efficient versatile memories with ferroelectric negative capacitance by gate-strain enhancement," IEEE Transactions on Electron Devices, vol. 64, no. 8, pp. 3498-3501, 2017.
    [21]C. Yang, Z. Yin, F. Zhang, Y. Su, F. Qin, and D. Wang, "Synergistic passivation effects of nitrogen plasma and oxygen plasma on improving the interface quality and bias temperature instability of 4H-SiC MOS capacitors," Applied Surface Science, vol. 513, p. 145837, 2020.
    [22]K.-S. Park, K.-H. Baek, D. Kim, J.-C. Woo, L.-M. Do, and K.-S. No, "Effects of N2 and NH3 remote plasma nitridation on the structural and electrical characteristics of the HfO2 gate dielectrics," Applied Surface Science, vol. 257, no. 4, pp. 1347-1350, 2010.
    [23]Y. Lee et al., "Effect of nitrogen incorporation in HfO2 films deposited by plasma-enhanced atomic layer deposition," Journal of The Electrochemical Society, vol. 153, no. 4, p. G353, 2006.
    [24]T. Schenk et al., "About the deformation of ferroelectric hystereses," Applied physics reviews, vol. 1, no. 4, p. 041103, 2014.
    [25]M. Jerman, Z. Qiao, and D. Mergel, "Refractive index of thin films of SiO2, ZrO2, and HfO2 as a function of the films’ mass density," Applied optics, vol. 44, no. 15, pp. 3006-3012, 2005.
    [26]O. Stenzel et al., "The correlation between mechanical stress, thermal shift and refractive index in HfO2, Nb2O5, Ta2O5 and SiO2 layers and its relation to the layer porosity," Thin Solid Films, vol. 517, no. 21, pp. 6058-6068, 2009.

    無法下載圖示 電子全文延後公開
    2025/08/24
    QR CODE