Activation and deactivation in heavily boron-doped silicon

Abstract

A shallow p(+)/n junction was formed using a ultra-low-energy (ULE) implanter. Activation by rapid thermal annealing (RTA) exhibited both solid phase epitaxy, in which the sheet resistance dropped rapidly, and reverse annealing, in a manner similar to furnace annealing. The temperature ranges in which these phenomena were observed, however, were higher in the case of RTA processing than they were in the case of furnace annealing due to the low thermal budget associated with the former. Deactivation phenomena were investigated for the shallow source/drain junction based on measurements of the post-annealing time and temperature following the RTA treatments. We found that the deactivation kinetics was divided into two regions. In the first regions, the rate of deactivation increased exponentially with the annealing temperature up to 850 degreesC. In the second regions, it was,found to decrease linearly with the annealing temperature beyond 850 degreesC. We believe that the first region is kinetically limited while the second is thermodynamically limited. We also observed "transient enhanced deactivation" an anomalous increase in the sheet resistance during the early stage of annealing at temperatures higher than 800 degreesC. The activation energy for transient enhanced deactivation was measured to be in the 1.75-1.87 eV range while that for normal deactivation was found to be between 3.49 and 3.69 eV.