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Proximity Gettering Design of Silicon Wafers Using Hydrocarbon Molecular Ion Implantation Technique for Advanced CMOS Image Sensors

Authors
Kurita, KazunariKadono, TakeshiShigematsu, SatoshiHirose, RyoOkuyama, RyosukeOnaka-Masada, AyumiOkuda, HidehikoKoga, YoshihiroPark, Jea-Gun
Issue Date
Sep-2018
Publisher
Institute of Electrical and Electronics Engineers Inc.
Keywords
CMOS image sensor; dark current; floating diffusion amplifier; metallic impurity contamination; molecular ion implantation; proximity gettering technique
Citation
Proceedings of the International Conference on Ion Implantation Technology, v.2018, no.September, pp.275 - 286
Indexed
SCOPUS
Journal Title
Proceedings of the International Conference on Ion Implantation Technology
Volume
2018
Number
September
Start Page
275
End Page
286
URI
https://scholarworks.bwise.kr/hanyang/handle/2021.sw.hanyang/4679
DOI
10.1109/IIT.2018.8807961
ISSN
0000-0000
Abstract
The metallic impurity gettering capability of hydrocarbon molecular ion-implanted silicon wafers was demonstrated by using a complementary metal-oxide-semiconductor (CMOS) image sensor that provides floating diffusion amplifier voltage (Vdark) output signals under dark conditions. It was found that the Vdark output signals of hydrocarbon molecular ion implanted p/p- and p/p+ silicon wafers did not increase after intentional contamination with Fe, Cu, Ni and Co metallic impurities. This indicates that the hydrocarbon molecular ion implanted silicon wafers were able to getter metallic impurities in the projection range of hydrocarbon molecular ion implantation during CMOS device fabrication. It was also found that the hydrocarbon-molecular-ion-implanted silicon wafers had improved electrical device performance factors, such as pn-junction leakage current, in actual device process lines. This gettering technique has no dependence on the silicon wafer substrates such as whether it is composed of bulk por p+ boron doped silicon crystals. We believe that the hydrocarbon-molecular-ion-implanted silicon wafers will be advantages for advanced CMOS image sensor fabrication.
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