-Again, we would like to point out that it is not our purpose to
-separate defects by a large distance in order to approximate the
-situation of isolated defects. However, we find that for increasing
-defect distances, configurations appear, which converge to the
-energetics of two isolated defects. This is indicated by the (absolute
-value of the) binding energy, which is approaching zero with
-increasing distance. From this, we conclude a decrease in interaction,
-which is already observable for defect separation distances accessible
-in our simulations.
-
-Nevertheless, the focus is on closely neighbored, interacting defects
-(for which an interaction with their own image is, therefore, supposed
-to be negligible, too). In fact, combinations of defects exhibiting
-equivalent distances were successfully modeled in a supercell
-containing 216 atoms in PRB 66, 195214 (2002). At no time, our aim was
-to investigate single isolated defect structures and their properties
-by a structure with increased separation distance of the two defects.
+The calculations criticized by the referee did not aim at the
+properties of isolated, non-intertacting defects, but rather at the
+defect-defect interaction. Single defects were modeled in separate
+simulation runs. However, we did find that for increasing defect
+distances, configurations appear, which converge to the energetics of
+two isolated defects. This is indicated by the (absolute value of the)
+binding energy, which is approaching zero with increasing distance.
+From this, we conclude a decrease in interaction, which is already
+observable for defect separation distances accessible in our
+simulations. Combinations of defects with similar distances were
+already successfully modeled in a supercell containing 216 atoms as
+described in PRB 66, 195214 (2002).