Using molecular-dynamics simulation techniques, we have investigated the ro
le that point defects and interstitial-vacancy complexes have on the silico
n amorphization process. We have observed that accumulation of interstitial
-vacancy complexes in concentrations of 25% and above lead to homogeneous a
morphization. However, we have determined the basic properties of the inter
stitial-vacancy complex, and showed that it is not as stable at room temper
ature as previously reported by other authors. From our simulations we have
identified more stable defect structures, consisting of the combination of
the complex and Si self-interstitials. These defects form when there is an
excess of interstitials or by incomplete interstitial-vacancy recombinatio
n in a highly damaged lattice. Unlike the interstitial-vacancy complex. the
se defects could survive long enough at room temperature to act as embryos
for the formation of extended amorphous zones and/or point defect clusters.