簡易檢索 / 詳目顯示

研究生: 羅肇豐
LOU, Zhao-Feng
論文名稱: 鐵電電晶體之類比式操作與後段製程相容之設計
Design of Ferroelectric Field-Effect-Transistor for Analog Operation and Back end of line (BEOL) Compatible Process
指導教授: 李敏鴻
Lee, Min-Hung
口試委員: 陳邦旭
Chen, Pang-Shiu
陳奕君
Cheng, I-Chun
唐英瓚
Tang, Ying-Tsang
李敏鴻
Lee, Min-Hung
口試日期: 2022/07/27
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: 2022
畢業學年度: 110
語文別: 中文
論文頁數: 69
中文關鍵詞: 鐵電材料多階記憶體HfZrO2氧化銦
英文關鍵詞: ferroelectric material, multibit, multilevel cell, HfZrO2, indium oxide
研究方法: 實驗設計法現象分析內容分析法
DOI URL: http://doi.org/10.6345/NTNU202201212
論文種類: 學術論文
相關次數: 點閱:166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
  • 為達到人工智能(AI)之物聯網(IoT)及高速傳輸之5G/6G科技,高密度的記憶體內/近運算高度需求。近年來各方領域的近記憶體運算與記憶體內建邏輯紛紛被提出,利用各種新興非揮發性記憶體(Emerging non-volatile memory, e-NVM) ,以實現內部存取並執行邏輯操作減少耗時與耗能的問題。本論文便是討論鐵電電晶體之類比式操作與後段製程相容之設計。
    研究中採用直流 (DC) 掃描、脈衝測量、Endurance和Retention的方法來研究元件特性。因此,第二章會介紹實驗的測量設備和波形設置。
    在第三章中,驗證雙 HZO 鐵電場效應電晶體 (FeFET) 可多階操作 (MLC)以 提高NVM密度。與單HZO FeFET 相比,金屬層/鐵電層/金屬層/鐵電層/矽基板 (MFMFS) FeFET 能夠在 ±3 V 的超低寫入/抹除電壓 (VP/E) 下實現2-bit位操作,並具有穩定的數據保持能力>104秒和>107次循環的耐用性。此外,通過使用金屬層/鐵電層/介電層/鐵電層/矽基板結構將記憶窗戶(MW)擴大至2.6 V,讀取錯誤率(ER)比單HZO低600倍。兩種雙HZO FeFET都通過使用電壓調整的方案展示具有高度線性和對稱性的深度學習能力。
    在第四章中,完成具有>106高開關電流比(Ion/Ioff)和4cm2/V⸳s 遷移率的無退火 In2O3 薄膜電晶體 (TFT),採用20sccm的Ar和15 W的濺射系統沉積。最後將鐵電電容與In2O3-TFT串聯,成功觀察到磁滯特性,並完成FE電容與In2O3-TFT的面積比對磁滯差異進行實驗驗證。因此,In2O3-TFT 有望在未來與鐵電記憶體整合,用於後端製程 (BEOL)。

    In order to achieve internet of thing (IoT) for artificial intelligence (AI) and high-speed communication with 5G/6G, the high-density in/near-memory-computing is urgently demanded. Recently, the in/near-memory-computing for kinds of Emerging non-volatile memory (eNVM) were proposed to reduce power consumption and time. In this thesis, the design of ferroelectric Field-Effect-Transistor (FeFET) for analog operation and Back end of line (BEOL) compatible process will be investigated.
    In Chapter 2, the measurement tools and technique will be introduced, such as direct current (DC) sweep, pulse measurement, endurance, and retention, as well as waveform setup for following experiment.
    In chapter 3, the double-HZO ferroelectric field-effect transistors (FeFETs) exhibits multilevel cell (MLC) to enhance NVM density. As compare to single-HZO FeFETs, metal/ferroelectric/metal/ferroelectric/Si (MFMFS) FeFETs has achieved 2-bit operation under ultra-low program/erase voltage (VP/E) of ±3 V with stable data retention of >104 s and robust endurance of 107 cycles. In addition, the enhancement of memory window (MW) with 2.6 V by using metal/ferroelectric/insulator/ferroelectric/Si leads to 600x lower error rate (ER) than single-HZO. Both double-HZO FeFETs demonstrated the capability of deep neural network (DNN) with nonlinearity and symmetry synaptic operation by using amplitude modulation scheme.
    In chapter 4, In2¬O¬3 thin film transistors (TFTs) with annealing-free exhibits high on/off-state current ratio of >106 with mobility of 4 cm2/V⸳s.¬, which fabricated by sputtering system with 20 sccm of Ar and 15 W. The proposed In2O3-TFT connected with ferroelectric capacitor in series to validate hysteretic characteristics. The Vt related to the area ratio of FE capacitor and In2O3-TFT. The In2O3-TFT is promising to integrated for ferroelectric memory toward back end of line (BEOL) in the future.

    中文摘要 I Abstract II 致謝 III 目錄 IV 圖目錄 VI 表目錄 IX 1 第一章 緒論 1 1-1 記憶體簡介 1 1-2 鐵電記憶體簡介 3 1-3 HfO2-based摻雜比例特性 4 2 第二章 量測儀器介紹 6 2-1 量測機台介紹 6 2-2 量測波型設定 8 2-3 量測波型設計 11 3 第三章 雙層鐵電氧化鉿鋯(FE-HZO)場效電晶體(FET) 14 3-1 簡介 14 3-2 實驗方法與步驟 18 3-3 雙層鐵電氧化鉿鋯電晶體之元件特性 19 3-4 雙層鐵電氧化鉿鋯電晶體之多階操作 23 3-5 雙層鐵電氧化鉿鋯電晶體之深度學習 28 3-6 結果討論 34 3-7 結論 36 4 第四章 氧化銦電晶體 37 4-1 簡介 37 4-2 氧化物半導體結合鐵電材料最新發展 38 4-3 氧化銦電晶體製程 43 4-4 氧化銦電晶體電性 47 4-5 鐵電材料與氧化銦電晶體結合 48 4-6 鐵電電容與氧化銦電晶體串聯 50 4-7 結果討論 58 4-8 結論 59 5 第五章 結論與未來工作 60 5-1 結論 60 5-2 未來工作 61 References 62 Publications 67 期刊論文 67 研討會論文 68

    [1] A. Sebastian, "In-memory computing for AI," Short Course, 2019 IEDM, Dec. 8 2019
    [2] K.-Y. Hsiang et al., "Ferroelectric HfZrO2 with electrode engineering and stimulation schemes as symmetric analog synaptic weight element for deep neural network training," IEEE Transactions on Electron Devices, vol. 67, no. 10, pp. 4201-4207, 2020.
    [3] P. Machanick, "Approaches to addressing the memory wall," School of IT and Electrical Engineering, University of Queensland, 2002.
    [4] A. Sebastian, "Ferroelectricity in Materials and Device Applications," Short Course, 2022 VLSI-TSA, April 18. 8 2022
    [5] G. Sun et al., "Memory that never forgets: emerging nonvolatile memory and the implication for architecture design," National Science Review, vol. 5, no. 4, pp. 577-592, 2018.
    [6] M. H. Park et al., "Review and perspective on ferroelectric HfO2-based thin films for memory applications," MRS Communications, vol. 8, no. 3, pp. 795-808, 2018.
    [7] J. Muller et al., "Ferroelectricity in simple binary ZrO2 and HfO2," Nano letters, vol. 12, no. 8, pp. 4318-4323, 2012.
    [8] B1500A Semiconductor Device Analyzer user’s manual,pp.1,4-2,32.
    [9] Agilent B Pulsed-IV Parametric Test Solutions,pp5-13
    [10] J. Müller, T.S. Böscke, S. Müller, E. Yurchuk, P. Polakowski, J. Paul, D. Martin, T. Schenk, K. Khullar, A. Kersch, W. Weinreich, S. Riedel, K. Seidel, A. Kumar, T.M. Arruda, S.V. Kalinin, T. Schlösser, R. Boschke, R. van Bentum, U. Schröder, and T. Mikolajick, “ Ferroelectric Hafnium Oxide: A CMOS-compatible and highly scalable approach to future ferroelectric memories, ” in IEDM Tech. Dig., Dec. 2013, pp. 280-283.
    [11] M. H. Lee, P.-G. Chen, C. Liu, K-Y. Chu, C.-C. Cheng, M.-J. Xie, S.-N. Liu, J.-W. Lee, S.-J. Huang, M.-H. Liao, M. Tang, K.-S. Li and M.-C. Chen, “Prospects for Ferroelectric HfZrOx FETs with Experimentally CET=0.98nm, SSfor=42mV/dec, SSrev=28mV/dec, Switch-OFF <0.2V, and Hysteresis-Free Strategies, ” Technical Digest, International Electron Device Meeting (IEDM), Washington D.C., pp. 616-619, Dec. 7-9, 2015.
    [12] M. H. Park, H. J. Kim, Y. J. Kim, T. Moon, K. D. Kim, and C. S. Hwang, “Toward a multifunctional monolithic device based on pyroelectricity and the electrocaloric effect of thin antiferroelectric HfXZr1−XO2 films, ” Nano Energy, vol. 12, pp. 131-140, Mar. 2015.
    [13] R. Eskandari, X. Zhang, and L. M. Malkinski, “Polarization-dependent photovoltaic effect in ferroelectric-semiconductor system, ” Appl. Phys. Lett., vol. 110, 121105, 2017.
    [14] M. H. Lee, K.-T. Chen, C.-Y. Liao, G.-Y. Siang, C. Lo, H.-Y. Chen, Y.-J. Tseng, C.-Y. Chueh, C. Chang, Y.-Y. Lin, Y.-J. Yang, F.-C. Hsieh, S. T. Chang, M.-H. Liao, K.-S. Li, and C. W. Liu, “Bi-directional Sub-60mV/dec, Hysteresis-Free, Reducing Onset Voltage and High Speed Response of Ferroelectric-AntiFerroelectric Hf0.25Zr0.75O2 Negative Capacitance FETs, ” in IEDM Tech. Dig., Dec. 2019, pp. 566-569.
    [15] M. H. Lee, K.-T. Chen, C.-Y. Liao, S.-S. Gu, G.-Y. Siang, Y.-C. Chou, H.-Y. Chen, J. Le, R.-C. Hong, Z.-Y. Wang, S.-Y. Chen, P.-G. Chen, M. Tang, Y.-D. Lin, H.-Y. Lee, K.-S. Li, and C. W. Liu, “Extremely Steep Switch of Negative-Capacitance Nanosheet GAA-FETs and FinFETs, ” Technical Digest, International Electron Device Meeting (IEDM), pp. 735-738, San Francisco, Dec. 1-5, 2018.
    [16] K. Chatterjee, S. Kim, G. Karbasian, A. J. Tan, A. K. Yadav, A. I. Khan, C. Hu, and S. Salahuddin, “Self-Aligned, Gate Last, FDSOI, Ferroelectric Gate Memory Device With 5.5-nm Hf0.8Zr0.2O2, High Endurance and Breakdown Recovery, ” IEEE Electron Device Letter, vol. 38, no. 10, pp. 1379-1382, Oct. 2017.
    [17] S. Dünkel, M. Trentzsch, R. Richter, P. Moll, C. Fuchs, O. Gehring, M. Majer, S. Wittek, B. Müller, T. Melde, H. Mulaosmanovic, S. Slesazeck, S. Müller, J. Ocker, M. Noack, D.-A. Löhr, P. Polakowski, J. Müller, T. Mikolajick, J. Höntschel, B. Rice, J. Pellerin, and S. Beyer, “A FeFET based super-low-power ultra-fast embedded NVM technology for 22nm FDSOI and beyond, ” IEDM, pp. 485-488, 2017.
    [18] M. Trentzsch, S. Flachowsky, R. Richter, J. Paul, B. Reimer, D. Utess, S. Jansen, H. Mulaosmanovic, S. Müller, S. Slesazeck, J. Ocker, M. Noack, J. Müller, P. Polakowski, J. Schreiter, S. Beyer, T. Mikolajick, and B. Rice, “A 28nm HKMG super low power embedded NVM technology based on ferroelectric FETs, ” IEDM, pp. 294-297, 2016.
    [19] R. Cao, Y. Wang, S. Zhao, Y. Yang, X. Zhao, W. Wang, X. Zhang , H. Lv, Q. Liu, and M. Liu, “Effects of Capping Electrode on Ferroelectric Properties of Hf0.5Zr0.5O2 Thin Films, ” IEEE Electron Device Letter, vol. 39, no. 8, pp. 1207-1210, Aug. 2018.

    [20] K. T. Chen, C. Y. Liao, C. Lo, H. Y. Chen, G. Y. Siang, S. Liu, S. C. Chang, M. H. Liao, S. T. Chang, and M. H. Lee*, “Improvement on Ferroelectricity and Endurance of Ultra-Thin HfZrO2 Capacitor with Molybdenum Capping Electrode, ” The 3rd Electron Devices Technology and Manufacturing (EDTM), Mat 1: Ferroelectric Materials and Devices, Singapore, Mar. 13-15, 2019.
    [21] H. J. Kim, M. H. Park, Y. J. Kim, Y. H. Lee, W. Jeon, T. Gwon, T. Moon, K. D. Kim, and C. S. Hwang, “Grain size engineering for ferroelectric Hf0.5Zr0.5O2 films by an insertion of Al2O3 interlayer, ” Appl. Phys. Lett., 105, 192903, Nov. 2014.
    [22] M. H. Park, H. J. Kim, Y. J. Kim, T. Moon, and C. S. Hwang, “The effects of crystallographic orientation and strain of thin Hf0.5Zr0.5O2 film on its ferroelectricity, ” Appl. Phys. Lett., 104, 072901, Feb. 2014.
    [23] T. Kim, J. A. del Alamo and D. A. Antoniadis, “Dynamics of HfZrO2 Ferroelectric Structures: Experiments and Models, ” in IEDM Tech. Dig., Dec. 2020, pp. 441-444.
    [24] Kai Ni1 , Jeffrey Smith1 , Huacheng Ye1 , Benjamin Grisafe1 , G. Bruce Rayner3 , Andrew Kummel2, “ A Novel Ferroelectric Superlattice Based Multi-Level Cell Non-Volatile Memory ”, IEDM19-669, ©2019 IEEE
    [25] C.-Y. Liao, K.-Y. Hsiang, F.-C. Hsieh, S.-H. Chiang, S.-H. Chang, J.-H. Liu, C.-F. Lou, C.-Y. Lin, T.-C. Chen, C.-S. Chang, and M. H. Lee, “Multibit Ferroelectric FET Based on Nonidentical Double HfZrO2 for High-Density Nonvolatile Memory,” IEEE Electron Device Letter, 2021.
    [26] M. Jerry, P.-Y. Chen, J. Zhang, P. Sharma, K. Ni, S. Yu, S. Datta, “Ferroelectric FET analog synapse for acceleration of deep neural network training, ” in IEDM Tech. Dig., Dec. 2017, pp. 139-142.
    [27] K.-Y. Hsiang, C.-Y. Liao, K.-T. Chen, Y.-Y. Lin, C.-Y. Chueh, C. Chang, Y.-J. Tseng, Y.-J. Yang, M.-H. Liao, T.-H. Hou, C.-H. Wu, C.-C. Ho, J.-P. Chiu, C.-S. Chang, M. H. Lee , “Ferroelectric HfZrO2 With Electrode Engineering and Stimulation Schemes as Symmetric Analog Synaptic Weight Element for Deep Neural Network Training” in TED OCTOBER 2020, VOL. 67, NO. 10.
    [28] Z.-F. Lou, C.-Y. Liao, K.-Y. Hsiang, C.-Y. Lin, Y.-D. Lin, P.-C. Yeh, C.-Y. Wang, H.-Y. Yang, P.-J. Tzeng, T.-H. Hou, Y.-T. Tang, M. H. Lee, “Characterization of double HfZrO2 based FeFET toward low-voltage multi-level operation for high density nonvolatile memory,” in 2022 VLSI-TSA, Hsinchu, Taiwan, Apr. 18‒21, 2022, pp. 1‒2.
    [29] Vita P.-H. Hu, H.-H. Lin, Z.-A. Zheng, Z.-T. Lin, Y.-C. Lu, T.-Y. Ho, Y.-W. Lee, C.-W. Su and C.-J. Su, "Split-Gate FeFET (SG-FeFET) with Dynamic Memory Window Modulation for NonVolatile Memory and Neuromorphic Applications," Symposium on VLSI Technology, 2019, pp. T134-T135.
    [30] Vita P.-H. Hu, H.-H. Lin, Z.-A. Zheng, Z.-T. Lin, Y.-C. Lu, T.-Y. Ho, Y.-W. Lee, C.-W. Su and C.-J. Su, "Split-Gate FeFET (SG-FeFET) with Dynamic Memory Window Modulation for NonVolatile Memory and Neuromorphic Applications," Symposium on VLSI Technology, 2019, pp. T134-T135.
    [31] S. Datta, S. Dutta, B. Grisafe, J. Smith, S. Srinivasa, and H. Ye, “Back-end-of-line compatible transistors for monolithic 3-D integration,” IEEE Micro, vol. 39, no. 6, pp. 8-15, Nov. 2019, doi: 10.1109/MM.2019.2942978.
    [32] E. P. Denton, H. Rawson, and J. E Stanworth, “Vanadate glasses,” Nature, vol. 173, pp. 1030-1032, May 1954, doi: 10.1038/1731030b0.
    [33] H. Hosono, “Ionic amorphous oxide semiconductors: material design, carrier transport, and device application,” Journal of Non-Crystalline Solids, vol. 352, pp. 851-858, Apr. 2006, doi: 10.1016/j.jnoncrysol.2006.01.073.
    [34] M. Si, Z. Lin, Z. Chen, and P. D. Ye, “First demonstration of atomic-layer-deposited BEOL-compatible In2O3 3D Fin transistors and integrated circuit: high mobility of 113 cm2/V∙s, maximum drain current of 2.5 mA/μm and maximum voltage gain of 38 V/V in In2O3 inverter,” in VLSI symp., June 2021, T2-4.
    [35] M. Trentzsch, S. Flachowsky, R. Richter, J. Paul, B. Reimer, D. Utess, S. Jansen, H. Mulaosmanovic, S. Müller, S. Slesazeck, J. Ocker, M. Noack, J. Müller, P. Polakowski, J. Schreiter, S. Beyer, T. Mikolajick, and B. Rice, “A 28 nm HKMG super low power embedded NVM technology based on ferroelectric FETs,” in IEDM Tech. Dig., Dec. 2016, pp. 294–297, doi: 10.1109/IEDM.2016.7838397.
    [36] K.-T. Chen, H.-Y. Chen, C.-Y. Liao, G.-Y. Siang, C. Lo, M.-H. Liao, K.-S. Li, S. T. Chang, and M. H. Lee, “Non-volatile ferroelectric FETs using 5-nm Hf0.5Zr0.5O2 with high data retention and read endurance for 1T memory applications,” IEEE Electron Device Letters, vol. 40, no. 3, pp. 399–402, Mar. 2019, doi: 10.1109/LED.2019.2896231.
    [37] Z. Liang, K. Tang, J. Dong, Q. Li, Y. Zhou, R. Zhu, Y. Wu, D. Han, and R. Huang, “A novel high-endurance FeFET memory device based on ZrO2 anti-ferroelectric and IGZO channel,” in IEDM Tech. Dig., Dec. 2021, pp. 382-385.
    [38] High-performance BEOL-compatible atomic-layer-deposited In2O3 Fe-FETs enabled by channel length scaling down to 7 nm: achieving performance enhancement with large memory window of 2.2.V, long retention > 10 years and high endurance > 108 cycles,” in IEDM Tech. Dig., Dec. 2021, pp. 386-389.
    [39] M. Si, A. Charnas, Z. Lin, and P. D. Ye, “Enhancement-mode atomic-layer-deposited In2O3 transistors with maximum drain current of 2.2 A/mm at drain voltage of 0.7 V by low-temperature annealing and stability in hydrogen environment,” IEEE Transactions on Electron Devices, vol. 68, no. 3, pp. 1075-1080, Mar. 2021, doi: 10.1109/TED.2021.3053229.
    [40] M. Si, Z. Lin, Z. Chen, and P. D. Ye, “First demonstration of atomic-layer-deposited BEOL-compatible In2O3 3D Fin transistors and integrated circuits: high mobility of 113 cm2/V⸳s, maximum drain current of 2.5 mA/μm and maximum voltage gain of 38 V/V in In2O3 inverter,” in VLSI Symp., June 2021, T2-4.
    [41] M. Si, Y. Hu, Z. Lin, X. Sun, A, Charnas, D. Zheng, X. Lyu, H. Wang, K. Cho, and P. D. Ye, “Why In2O3 can make 0.7 nm atomic layer thin transistors,” Nano Letters, vol. 21, no. 1, pp. 500-506, Jan. 2021, doi: 10.1021/acs.nanolett.0c03967.
    [42] You Meng,a Guoxia Liu,a Ao Liu,a Huijun Song,a Yang Hou,a Byoungchul Shinb, “ Low-temperature fabrication of high performance indium oxide thin film transistors”, RSC Adv., 2015, 5, 37807, DOI: 10.1039/c5ra04145g
    [43] H.-I. Yeom, J. B. Ko, G. Mun and S.-H. Ko Park*, “ High mobility polycrystalline indium oxide thin-film transistors by means of plasma-enhanced atomic layer deposition†” , J. Mater. Chem. C, 2016, 4, 6873, DOI: 10.1039/c6tc00580b
    [44] Jaakko Leppäniemi , Olli-Heikki Huttunen , Himadri Majumdar , and Ari Alastalo *, Flexography-Printed In2O3 Semiconductor Layers for HighMobility Thin-Film Transistors on Flexible Plastic S 7168-7175, 2015. DOI: 10.1002/adma.201502569
    [45] Jiawei He, Guoli Li,* Yawei Lv, Chunlan Wang, Chuansheng Liu, Jinchai Li, Denis Flandre, Huipeng Chen, Tailiang Guo, and Lei Liao* “Defect Self-Compensation for High-Mobility Bilayer InGaZnO/In2O3 Thin-Film Transistor” Chem. C, 6873-6880, 2016., DOI: 10.1002/aelm.201900125

    無法下載圖示 本全文未授權公開
    QR CODE