Thermal stability of thin CoSi2 layers on polysilicon implanted with As, BF2, and Si

Abstract

The thermal stability of thin cobalt silicide layers grown on preamorphized chemical vapor deposited silicon layers has been studied in the temperature range between 950 and 1100 °C. The morphology of the starting layers and their evolution during the thermal processes was analyzed by transmission electron microscopy, atomic force microscopy and Rutherford backscattering spectroscopy. The observed increase in sheet resistance with the annealing time has been correlated to the agglomeration process taking into account the dependence of the resistivity on film thickness and carrier mean free path. Sheet resistance measurements have been used to study the agglomeration process of CoSi2 by varying temperature and substrate doping (As, BF2, and Si implants). The process is thermally activated with an activation energy of 4.3 eV for the Si implanted samples. The BF2 implanted substrate show a higher activation energy (∼5.4 eV), while the arsenic implanted a lower one (∼3.6 eV). This difference is attributed to the weakening of the Co–Si bonds by arsenic atoms and to the presence of some fluorine precipitates at the CoSi2/Si interface that increase the energy needed for the reaction at the silicide/silicon interface.