Using deep level transient spectroscopy (DLTS) measurements with
zero-bias and reverse-bias cooling, we have observed new metastable
defects (EM1, EM2 and EM3) in n-type silicon by hydrogen implantation
at temperature as low as 88 K. We have investigated the trap
parameters of these metastable defects and their concentration
depth profiles. Hydrogen ion implantation was performed with
energies of 80 keV, 90 keV, and 100 keV to a dose of
2 × 1010 cm−2.
The silicon substrate temperature was kept at as low
as 88 K during hydrogen implantation and then was raised naturally
to room temperature. From analysis of Arrhenius plots, the energy
levels of EM1, EM2 and EM3 are obtained to be Ec-0.29 eV, Ec-0.41 eV
and Ec-0.55 eV, respectively. The depth profiles of metastable
defects in 90-keV samples have a peak in the concentration around
the depth of 0.68 µm, which is shallow compared with the projected
range of 90 keV hydrogen. The peak position becomes deeper as the
energy of ion implantation increases. This indicates that the
production of metastable defects is caused by ion implantation.
Additionally, comparison with helium-implanted samples suggests
that implanted hydrogen is included in these metastable defects.