Grain boundary segregation of boron and sulfur and its effect on ductility in rapidly solidified Ni-base L12 compounds

This paper reports a study of boron segregation in Ni₃Al, Ni₃Si, Ni₃Ge, and Ni₃Ga. Sulfur segregation in Ni₃Al is also considered. The results show that boron segregates in Ni₃Al and that the amount of segregation tends to increase as the bulk concentration of boron in the alloy increases. However, because the samples had not reached equilibrium during the heat treatment, there was some scatter in this correlation. Boron also segregated in Ni₃Si and Ni₃Ge, but there appeared to be no dependence of the amount of segregation on the bulk concentration. This result is not surprising because in these alloys the boron concentration was above the solubility limit. Boron segregation also occurred in Ni₃Ga and it appeared to increase with increasing bulk concentration. However, only a small amount of data was obtained for this system. Sulfur segregated in Ni₃Al and its concentration on the grain boundaries increased with increasing bulk concentration. It did not appear to compete with boron for grain boundary sites. Aluminum also segregated in Ni₃Al, but there was a large amount of scatter in the data. The plastic strain to failure measured for the samples of Ni₃Al did not correlate with the amount of boron segregation. In particular, we could not explain the fact that boron additions enhance grain boundary cohesion more effectively in Ni-rich alloys by an increase in boron segregation in these alloys. Stoichiometric alloys and Ni-poor alloys that were very brittle had boron segregation in equivalent amounts to that found in ductile Ni-rich alloys.