4.6 Article

Dwell-Fatigue of Ni-Based Superalloys with Serrated and Planar Grain Boundary Morphologies: The Role of the γ′ Phase on Strain Accumulation and Cavitation

Publisher

SPRINGER
DOI: 10.1007/s11661-021-06454-8

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Funding

  1. National Science Foundation [CMMI 13-34664]
  2. Rolls-Royce Corporation
  3. Department of Defense through the National Defense Science and Engineering Graduate Fellowship Program (NDSEG)
  4. U.S. Department of Energy, Office of Basic Energy Sciences, Division of Materials Sciences and Engineering [DE-SC0014281]
  5. U.S. Department of Energy (DOE) [DE-SC0014281] Funding Source: U.S. Department of Energy (DOE)

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The study investigated the impact of grain boundary morphology on cavitation behavior in a Ni-based superalloy, RR1000, during elevated temperature dwell-fatigue. Results indicated that serrated GB morphologies increased the proclivity for cavity formation, with strain localization occurring near the GBs before cavity formation.
The effect of grain boundary (GB) morphology on the cavitation behavior in a Ni-based superalloy, RR1000, was studied during elevated temperature dwell-fatigue at 700 degrees C. Following a solution heat treatment, the material was control cooled at two different rates, resulting in high angle GB morphologies that were tailored as either serrated or planar. The resulting gamma ' precipitate structures were characterized near GBs and within grains. Along serrated GBs coarsened and elongated gamma ' precipitates formed and consequently created adjacent regions that were denuded of gamma ' precipitates. Cyclic dwell-fatigue experiments were performed at low and high stress amplitudes to vary the amount of imparted strain on the specimens. A combination of electron backscatter diffraction and digital image correlation were used to resolve strain localization relative to the GBs, in which strain accumulation was found to precede cavity formation. Additionally, the regions denuded of the gamma ' precipitates were observed to localize strain and to be initial sites of cavitation. These results present a quantitative strain analysis between two variants of an RR1000 alloy, which provides the micromechanical rationale to assess the increased proclivity for serrated GBs to form cavities.

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