Study of millisecond laser annealing on recrystallization, activation, and mobility of laser annealed SOI doped via arsenic ion implantation

Millisecond anneal techniques have been demonstrated to achieve fully recrystallized, highly activated, shallow, and abrupt junctions in silicon with both p- and n-type dopants due to the technique's fast time scale and high temperature. To understand and model the effects of millisecond laser annealing, knowledge of the true thermal profile experienced by the active semiconductor region must be known. This work simulates the impacts of a scanning laser in a series of shallow implants, and compares those results to experimental results. Arsenic ion (As+) implant energies of 10, 19, and 25 keV at doses of 1.5 × 1015 and 3 × 1015 cm−2 into a silicon-on-insulator substrate are studied to achieve different doping levels and amorphization depths. The recrystallization, activation, and mobility of the laser annealed, ion implanted experimental cells are then analyzed. For each experiment, Sentaurus technology computer aided design is used to create a calibrated 2D laser model to approximate the thermal budget o...