Silicon nanowire NVM cell using high-k dielectric charge storage layer

被引:10
|
作者
Zhu, X. [1 ,2 ]
Yang, Y. [1 ]
Li, Q. [1 ,2 ]
Ioannou, D. E. [1 ]
Suehle, J. S. [2 ]
Richter, C. A. [2 ]
机构
[1] George Mason Univ, ECE Dept, Fairfax, VA 22030 USA
[2] NIST, Div Semicond Elect, Gaithersburg, MD 20899 USA
来源
MICROELECTRONIC ENGINEERING | 2008年 / 85卷 / 12期
关键词
Silicon nanowire; Self-alignment; Non-volatile memory; Hafnium oxide;
D O I
10.1016/j.mee.2008.09.013
中图分类号
TM [电工技术]; TN [电子技术、通信技术];
学科分类号
0808 ; 0809 ;
摘要
Si nanowire (SiNW) channel non-volatile memory (NVM) cells were fabricated by a "self-alignment" Process. First, a layer of thermal SiO2 was grown on a silicon wafer by dry oxidation, and the SiNWs were then grown by chemical vapor deposition in pre-defined locations. This was followed by depositing the gate dielectric, which almost surrounds the nanowire and consists of three stacked layers: SiO2 blocking layer, HfO2 charge-storing layer and a thin tunneling oxide layer. Source/drain and gate electrodes were formed by photolithography and lift-off, and the devices were electrically tested. As expected from this fabrication process and the enhanced electrostatic control of the "surrounding" gate, excellent cell characteristics were obtained. (C) 2008 Elsevier B.V. All rights reserved.
引用
收藏
页码:2403 / 2405
页数:3
相关论文
共 50 条
  • [11] Performance analysis of silicon nanowire transistors considering effective oxide thickness of high-k gate dielectric
    Chandra, S. Theodore
    Balamurugan, N. B.
    JOURNAL OF SEMICONDUCTORS, 2014, 35 (04)
  • [12] Characterization of high-k gate dielectric/silicon interfaces
    Miyazaki, S
    APPLIED SURFACE SCIENCE, 2002, 190 (1-4) : 66 - 74
  • [13] Improvement of metal gate/high-k dielectric CMOSFETs characteristics by atomic layer etching of high-k gate dielectric
    Min, K. S.
    Park, C.
    Kang, C. Y.
    Park, C. S.
    Park, B. J.
    Kim, Y. W.
    Lee, B. H.
    Lee, Jack C.
    Bersuker, G.
    Kirsch, P.
    Jammy, R.
    Yeom, G. Y.
    SOLID-STATE ELECTRONICS, 2013, 82 : 82 - 85
  • [14] Performance Improvement of Polycrystalline Silicon Nanowire Thin-Film Transistors by a High-k Capping Layer
    Lee, Ko-Hui
    Hsu, Hsing-Hui
    Lin, Horng-Chih
    Huang, Tiao-Yuan
    JAPANESE JOURNAL OF APPLIED PHYSICS, 2009, 48 (02)
  • [15] Suppression of interfacial layer in high-K gate stack with crystalline high-K dielectric and AlN buffer layer structure
    Wang, Wei-Cheng
    Tsai, Meng-Chen
    Lin, Yi-Ping
    Tsai, Yi-Jen
    Lin, Hsin-Chih
    Chen, Miin-Jang
    MATERIALS CHEMISTRY AND PHYSICS, 2016, 184 : 291 - 297
  • [16] Amorphous oxide semiconductor memory using high-k charge trap layer
    Rha, S. -H.
    Jung, J. S.
    Kim, J. H.
    Kim, U. K.
    Chung, Y. J.
    Jung, H. -S
    Lee, S. Y.
    Hwang, C. S.
    THIN FILM TRANSISTORS 10 (TFT 10), 2010, 33 (05): : 375 - 380
  • [17] Characteristics Improvement of Silicon Nanowire Field Effect Transistor by using High-K Oxide Engineering
    Vimala, P.
    Bassapuri, Manjunath
    Maheshwari, Krishna
    2019 4TH INTERNATIONAL CONFERENCE ON ELECTRICAL, ELECTRONICS, COMMUNICATION, COMPUTER TECHNOLOGIES AND OPTIMIZATION TECHNIQUES (ICEECCOT), 2019, : 125 - 128
  • [18] Capacitance-voltage analysis of a high-k dielectric on silicon
    Davinder Rathee
    Sandeep K.Arya
    Mukesh Kumar
    半导体学报, 2012, 33 (02) : 10 - 13
  • [19] Capacitance-voltage analysis of a high-k dielectric on silicon
    Rathee, Davinder
    Arya, Sandeep K.
    Kumar, Mukesh
    JOURNAL OF SEMICONDUCTORS, 2012, 33 (02)
  • [20] Mobility Degradation Mechanisms of MOSFETs with a High-k Dielectric Layer
    Jung, Hyun Soo
    Ryu, Ju Tae
    Kim, Dong Hun
    Kim, Tae Whan
    JOURNAL OF NANOSCIENCE AND NANOTECHNOLOGY, 2014, 14 (11) : 8215 - 8218
12345