Abstract
Oxidized MC carbides which act as main crack initiation sites in a polycrystalline superalloy under thermal-mechanical fatigue (TMF) conditions at 850 °C were studied. Microstructural observations in the TMF tested specimens were compared to findings from bulk samples exposed isothermally in air at 850 °C for 30 hours in the absence of any external applied load. Carbides were found to oxidize rapidly after exposure at 850 °C for 30 hours resulting in surface eruptions corresponding to oxidation products, from where micro-cracks initiated. Plastic deformation due to volume expansion of the often porous oxidized carbides led to high dislocation densities in the adjacent matrix as revealed by controlled electron channeling contrast imaging. The high dislocation density facilitated the dissolution kinetics of γ′ precipitates by segregation and diffusion of chromium and cobalt along the dislocations via pipe diffusion, resulting in the formation of soft recrystallized grains. Atom probe tomography revealed substantial compositional differences between the recrystallized grains and the adjacent undeformed γ matrix. Similar observations were made for the TMF tested alloy. Our observations provide new insights into the true detrimental role of oxidized MC carbides on the crack initiation performance of polycrystalline superalloys under TMF.
Highlights
THE thermal-mechanical fatigue (TMF) performance of nickel-based superalloys is a critical parameter in designing new superalloys with superior lifetime and performance.[1]
For the polycrystalline nickel-based STAL15-CC superalloy, cracks initiate from surface-connected oxidized MC carbides when tested under of-phase thermal-mechanical fatigue (OP-TMF) conditions in the temperature range 100 °C to 850 °C
The recrystallization along the fracture surface is believed to be due to the oxidation and the associated volume mismatch leading apparently to local plasticity as the crack propagates, the extensive recrystallization in the vicinity of the oxidized carbide is not well understood and our investigations were focused on the rationalization of this microstructural observation
Summary
THE thermal-mechanical fatigue (TMF) performance of nickel-based superalloys is a critical parameter in designing new superalloys with superior lifetime and performance.[1]. Near-atomic scale characterization of solute segregation to dislocations by APT allows us to provide new insights into the diffusion of solutes such as chromium and cobalt along dislocations via pipe diffusion, which leads to local chemical inhomogeneities, facilitating dissolution of c¢ precipitates and the subsequent recrystallization in the vicinity of METALLURGICAL AND MATERIALS TRANSACTIONS A oxidized MC carbides, promoting crack propagation. These observations shed light onto the crack initiation mechanism
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