Title of article
Semiconductor surface and interface passivation by cyanide treatment
Author/Authors
H. Kobayashi، نويسنده ,
Issue Information
روزنامه با شماره پیاپی سال 2004
Pages
14
From page
279
To page
292
Abstract
Cyanide treatment which simply involves immersion of semiconductors in cyanide solutions can passivate interface states as
well as surface states. When Si surfaces are treated with KCN solutions, a surface photovoltage greatly increases, and the surface
recombination velocity is calculated to be decreased from 3000 cm/s to less than 200 cm/s. When the cyanide treatment is
applied to ultrathin SiO2/single-crystalline Si structure, interface states are passivated. The passivation of the SiO2/Si interface
states increases the energy conversion efficiency of hindium tin oxide (ITO)/SiO2/Sii MOS solar cells to 16.2% and decreases the
leakage current density for haluminum (Al)/SiO2/Sii MOS diodes to 1/3–1/8. When the cyanide treatment is performed on
polycrystalline (poly-) Si, defect states in Si up to at least 0.5 mm depth from the surface are passivated, resulting in a vast
increase in the energy conversion efficiency of hITO/SiO2/poly-Sii solar cells and a decrease in the dark current density of hAl/
SiO2/poly-Sii MOS diodes to 1/100–1/15 that without cyanide treatment. The defect passivation is attributed to the formation of
Si–CN bonds from defect states. Si–CN bonds are found not to be ruptured by heat treatment at 800 8C andAM1.5 100 mW/cm2
irradiation for more than 1000 h. Density functional calculations show that the thermal and irradiation stability results from
strong Si–CN bonds with the bond energy of 4.5 eV. When the cyanide treatment is performed on oxide/GaAs(1 0 0) structure,
the interface state density decreases to 50%. The cyanide treatment can also passivate defect states in Cu2O films, resulting in
increases in the carrier density and the band-to-band photoluminescence intensity.
# 2004 Elsevier B.V. All rights reserved
Keywords
Defect states , Si , Interface states , Silicon oxide , Cyanide treatment , MOS , Solar cells , Cu2O
Journal title
Applied Surface Science
Serial Year
2004
Journal title
Applied Surface Science
Record number
1000204
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