Si CMOS Image-Sensors Designed With Hydrogen-Ion Implantation Induced Nanocavities for Enhancing Output Voltage Sensing Margin via Proximity Gettering

Si CMOS Image-Sensors Designed With Hydrogen-Ion Implantation Induced Nanocavities for Enhancing Output Voltage Sensing Margin via Proximity Gettering

Si CMOS image-sensor (CIS) cells were designed by implementing proximity relaxation gettering sites of hydrogen-ion implantation-induced nanocavities (20-35 nm in diameter) underneath Si photodiode regions to enhance the sensing margin of output voltage in CIS cells. They enabled almost no degradati...

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Veröffentlicht in:IEEE transactions on electron devices 2017-05, Vol.64 (5), p.2345-2349
Hauptverfasser: Kim, Il-Hwan, Park, Jun-Seong, Shim, Tae-Hun, Park, Jea-Gun
Format: Artikel
Sprache:eng
Schlagworte:
Cavities
CMOS
CMOS image sensors (CIS)
Contaminants
Copper
Electric potential
Epitaxial growth
Gettering
hydrogen ion implantation
Hydrogen ions
Image enhancement
Ion implantation
Iron
Nickel
Photodiodes
Silicon
Transistors
Voltage
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Zusammenfassung:Si CMOS image-sensor (CIS) cells were designed by implementing proximity relaxation gettering sites of hydrogen-ion implantation-induced nanocavities (20-35 nm in diameter) underneath Si photodiode regions to enhance the sensing margin of output voltage in CIS cells. They enabled almost no degradation in the output voltage sensing margin, although ~10 14 cm -2 of Fe, Cu, Ni, and Co contaminants were introduced in the photodiode regions of CIS cells, demonstrating an excellent relaxation gettering ability. However, Si CIS cells designed with p/p ++ epitaxial wafers, which are widely used, showed that the sensing margin of the CIS cells significantly decreased as the concentration of Cu and Ni contaminants in the Si photodiode regions increased, indicating no segregation gettering ability.
ISSN:0018-9383
1557-9646
DOI:10.1109/TED.2017.2677948