Evolution of end-of-range damage and transient enhanced diffusion of indium in silicon

Correlation of evolution of end-of-range (EOR) damage and transient enhanced diffusion (TED) of indium has been studied by secondary ion mass spectrometry and transmission electron microscopy. A physically based model of diffusion and defect growth is applied to the indium diffusion system. Indium implantation with 200 keV, 1x10(14)/cm(2) through a 10 nm screen oxide into < 100 > p-type Czochralski silicon wafer was performed. During postimplantation anneal at 750 degreesC for times ranging from 2 to 120 min, formation of dislocation loops and indium segregation into loops were observed. Simulation results of evolution of EOR defects show that there is a period that {311} defects dissolve and release free interstitials before the Ostwald ripening step of EOR dislocation loops. Our diffusion model that contains the interaction between indium and loops shows the indium pileup to the loops. Indium segregation to loops occurs at a pure growth step of loops and continues during the Ostwald ripening step. Although dislocation loops and indium segregation in the near-surface region are easily dissolved by high temperature annealing, EOR dislocation loops in the bulk region are rigid and well grown. It is considered that indium trapped by loops with a large radius is energetically stable. It is shown that modeling of the evolution of EOR defects is important for understanding indium TED. (C) 2002 American Institute of Physics.