Competing influence of damage buildup and lattice vibrations on the shape of ion range profiles in Si

Phosphorus depth profiles in Si obtained by 140 keV implantation into the [001] axial channel direction and into a direction 7⁰ off axis are investigated at two different doses (5x10¹³ and 5x10¹⁵ cm^-2)for implantation temperatures of 350 ⁰C and room temperature (RT). At low dose and at channeling incidence, the penetration depth of implanted ions is higher at RT than at 350 ⁰C This behavior is caused by the dechanneling of lattice vibrations. At high dose, the temperature dependence of the shape of the implantation profiles is opposite that at low dose, due to the enhanced dechanneling by defect accumulation at RT. On the other hand, damage buildup does not occur at elevated temperature. The temperature dependence of the profiles obtained by tilted implantation is much less than for the channeled implants. The P profiles measured can be reproduced very well by atomistic simulations which take into account both lattice vibrations and defect accumulation during ion bombardment.