Process-induced defects are a serious issue for modern sub-micron
Si LSIs. To characterize such defects, two different techniques
are useful: electrically detected magnetic resonance (EDMR) and
transmission electron microscope (TEM), which can detect small
(point) and extended defects, respectively. We applied EDMR and
TEM to the issue of defect-induced leakage currents in
dynamic-random-access memory (DRAM) cells. For our DRAM samples
(a 0.25-μm-rule series), although TEM showed no extended defects,
EDMR successfully detected two types of point defects:
V2+Ox (Si divacancy-oxygen complexes) and larger Si vacancies
(at least larger than V6). We confirmed that these defects are the
source of DRAM leakage currents. The observed defects were formed by ion
implantation processes, but were more thermally stable than those in bulk
Si crystals. The origins of this enhanced stability are attributed to the
presence of oxygen atoms and a strong mechanical strain in LSIs. To clarify
the origin of the complicated strain in LSI structures, we can directly
measure the local-strain distribution in DRAM samples by means of
convergent-beam electron diffraction (CBED) using TEM, which provides us
with a valuable hint for understanding the formation mechanism of
process-induced defects.