Curing Process on Passivation Layer for Backside-Illuminated CMOS Image Sensor Application

被引:0
|
作者
Park, Jongseo [1 ]
Choi, Kyeong-Keun [2 ]
An, Jehyun [1 ]
Kang, Bohyeon [1 ]
You, Hyeonseo [1 ]
Hong, Giryun [1 ]
Ahn, Sung-Min [1 ]
Baek, Rock-Hyun [1 ]
机构
[1] Pohang Univ Sci & Technol POSTECH, Dept Elect Engn, Pohang 37673, South Korea
[2] Pohang Univ Sci & Technol POSTECH, Natl Inst Nanomat Technol NINT, Pohang 37673, South Korea
来源
IEEE ACCESS | 2023年 / 11卷
基金
新加坡国家研究基金会;
关键词
Plasma-enhanced atomic layer deposition; forming gas annealing; CMOS image sensor; surface passivation; SiO2; HfO2; CAPACITANCE-VOLTAGE HYSTERESIS; FREQUENCY DISPERSION; BORDER TRAPS; FIXED CHARGE; DEPOSITION; SILICON; PERFORMANCE; INTERFACE; FILMS;
D O I
10.1109/ACCESS.2023.3286976
中图分类号
TP [自动化技术、计算机技术];
学科分类号
0812 ;
摘要
We fabricated Al/Al2O3/SiO2/Si and Al/HfO2/Si structures to optimize the passivation layer of a backside-illuminated (BSI) complementary metal oxide semiconductor (CMOS) image sensor (CIS), with the key properties of the newly developed high-k passivation layer analyzed via border traps, interface traps, and fixed charges. In the first experiment using Al2O3/SiO2 bilayer-based structures, different thicknesses of SiO2 were applied from 0 to 15 nm. The improvement in their properties was confirmed by applying forming gas annealing (FGA), a type of post-treatment, to all experimental systems. The first experiment results indicated that both the SiO2 layer and FGA were effective for chemical passivation. However, a tradeoff occurred in the degree of improvement of the interface trap density (D-it) and fixed-charge density (Q(f)) according to the SiO2 layer thickness. Subsequently, in the second experiment using HfO2 single-layer-based structures, FGA improved the border trap to a relatively poor extent compared to the first experiment. Nevertheless, FGA improved the electrical characteristics of the HfO2 films without any side effects and results in optimal Dit and |Q(f)/q| values of 2.59 x 10(11) eV(-1) cm(-2) and 1.00 x 10(12) cm(-2), respectively, demonstrating its potential for the passivation layer in BSI CIS applications.
引用
下载
收藏
页码:60660 / 60667
页数:8
相关论文
共 50 条
  • [21] Realization and application of a 111 million pixel backside-illuminated detector and camera
    Zacharias, Norbert
    Dorland, Bryan
    Bredthauer, Richard
    Boggs, Kasey
    Bredthauer, Greg
    Lesser, Mike
    FOCAL PLANE ARRAYS FOR SPACE TELESCOPES III, 2007, 6690
  • [22] A simulation analysis of backside-illuminated multi-collection-gate image sensor employing Monte Carlo method
    Shimonomura, Kazuhiro
    Dao, Vu Truong Son
    Etoh, Takeharu G.
    Kamakura, Yoshinari
    2014 INTERNATIONAL CONFERENCE ON SIMULATION OF SEMICONDUCTOR PROCESSES AND DEVICES (SISPAD), 2014, : 205 - 208
  • [23] Suppression of Crosstalk by Using Backside Deep Trench Isolation for 1.12μm Backside Illuminated CMOS Image Sensor
    Kitamura, Y.
    Aikawa, H.
    Kakehi, K.
    Yousyou, T.
    Eda, K.
    Minami, T.
    Uya, S.
    Takegawa, Y.
    Yamashita, H.
    Kohyama, Y.
    Asami, T.
    2012 IEEE INTERNATIONAL ELECTRON DEVICES MEETING (IEDM), 2012,
  • [24] High-Voltage Backside-Illuminated CMOS Photovoltaic Module for Powering Implantable Temperature Sensors
    Hung, Yung-Jr
    Cai, Meng-Syuan
    Chen, Jia-Fa
    Su, Hsiu-Wei
    Jen, Po-Chang
    Chen, Poki
    Shih, Chih-Cheng
    Chang, Ting-Chang
    IEEE JOURNAL OF PHOTOVOLTAICS, 2018, 8 (01): : 342 - 347
  • [25] Process Integration of 3D Stacking for Backside Illuminated Image Sensor
    Hsiao, Zhi-Cheng
    Ko, Cheng-Ta
    Chang, Hsiang-Hung
    Fu, Huan-Chun
    Hsu, Chao-Kai
    Li, Shu-Man
    Tsai, Wen-Li
    Shen, Wen-Wei
    Wang, Jen-Chun
    Lin, Yu-Min
    Lo, Wei-Chung
    2014 INTERNATIONAL CONFERENCE ON ELECTRONICS PACKAGING (ICEP), 2014, : 82 - 85
  • [26] Process Integration of Backside Illuminated Image Sensor with Thin Wafer Handling Technology
    Chang, H. H.
    Chien, C. H.
    Fu, H. C.
    Tsai, W. L.
    Chiang, C. W.
    Ko, C. T.
    Chen, Y. H.
    Lo, W. C.
    Su, K. C.
    Li, C. S.
    2013 IEEE 63RD ELECTRONIC COMPONENTS AND TECHNOLOGY CONFERENCE (ECTC), 2013, : 1880 - 1886
  • [27] Backside-illuminated scientific CMOS detector for soft X-ray resonant scattering and ptychography
    Desjardins, Kewin
    Medjoubi, Kadda
    Sacchi, Maurizio
    Popescu, Horia
    Gaudemer, Roland
    Belkhou, Rachid
    Stanescu, Stefan
    Swaraj, Sufal
    Besson, Adrien
    Vijayakumar, Jaianth
    Pautard, Stephanie
    Noureddine, Arafat
    Mercere, Pascal
    Da Silva, Paulo
    Orsini, Fabienne
    Menneglier, Claude
    Jaouen, Nicolas
    JOURNAL OF SYNCHROTRON RADIATION, 2020, 27 : 1577 - 1589
  • [28] Enhanced Efficiency in Backside-Illuminated Deep-n-Well-Assisted CMOS Photovoltaic Devices
    Hung, Yung-Jr
    Su, Hsiu-Wei
    Chun, Chung-Lin
    Chen, Jia-Fa
    Huang, Chia-Wei
    Cai, Meng-Syuan
    IEEE ELECTRON DEVICE LETTERS, 2015, 36 (11) : 1169 - 1171
  • [29] Energy- and spatial-resolved detection using a backside-illuminated CMOS sensor in the soft X-ray region
    Harada, Tetsuo
    Teranishi, Nobukazu
    Watanabe, Takeo
    Zhou, Quan
    Yang, Xiao
    Bogaerts, Jan
    Wang, Xinyang
    APPLIED PHYSICS EXPRESS, 2019, 12 (08)
  • [30] A Novel 3D Integration Scheme for Backside Illuminated CMOS Image Sensor Devices
    Ko, Cheng-Ta
    Hsiao, Zhi-Cheng
    Chang, Hsiang-Hung
    Lyu, Dian-Rong
    Hsu, Chao-Kai
    Fu, Huan-Chun
    Chien, Chun-Hsien
    Lo, Wei-Chung
    Chen, Kuan-Neng
    IEEE TRANSACTIONS ON DEVICE AND MATERIALS RELIABILITY, 2014, 14 (02) : 715 - 720
12345