Effect of carbon content on the microstructure and creep properties of a 3rd generation single crystal nickel-base superalloy

Abstract

Effect of carbon content on the microstructure and creep properties of a 3rd generation single crystal nickel-base superalloy has been investigated by the scanning electron microscope, X-ray computed tomography and electron probe microanalyzer. With the increase of the carbon content, MC carbides evolve from octahedral to well-developed dendrite, which promotes the formation of microporosity. Moreover, the volume fraction of porosity increases in the experimental alloys after solution heat treatment. As a result, the increase in the size of MC carbides and the porosity has a detrimental effect on the low temperature and high stress creep behavior of the alloys. The specimen crept at 850°C and 586MPa with the carbon content of 430ppm shows the shortest rupture life due to the largest primary creep strain. However, the creep behavior of the alloy at 1120°C and 140MPa gets better as the carbon content increases from 88 to 430ppm. TCP phase is observed near the fracture surfaces of the alloys, which explores as a potential cause for the creep rupture. However, the formation of TCP phase is effectively suppressed for decreasing segregation of the alloying elements, which results in the improvement of the creep life in the alloy with 430ppm carbon at 1120°C and 140MPa.