Strengthening mechanisms for microstructures containing unimodal and bimodal γ′ precipitates in ATI 718Plus

Geeta Kumari, M. Sundararaman, Carl J. Boehlert, Chanchal Ghosh, R. Mythili, Arup Dasgupta, Jonathan D. Poplawsky, S. Sankaran

Research output: Contribution to journalArticlepeer-review

Abstract

The influence of γ′ precipitate size distribution on the deformation mechanisms under tensile loading in ATI 718Plus was studied. A set of aging treatments within the temperature range of 720 °C–900 °C was performed on solution-treated samples to obtain various γ′ precipitate size distributions. Unimodal and bimodal γ′ precipitate size distributions were achieved through single-step and two-step aging sequences, respectively, and such microstructures were tensile tested to failure to assess their yield strength, ultimate tensile strength, and elongation-to-failure. Some of the tensile samples were interrupted after achieving 3–4 % plastic strain, and the deformed microstructures were examined using transmission electron microscopy to investigate the γ′ precipitate-dislocation interactions. For the unimodal γ′ precipitate size distribution samples with the smaller γ′ precipitates (radius ∼ 7 nm), dislocations sheared through the precipitates. Both dislocation loops and paired dislocations were observed for the microstructures containing larger γ′ precipitates (radius ∼ 24 nm). The microstructure containing a bimodal γ′ precipitate size distribution, which included average γ′ precipitate radii of ∼6 nm and ∼28 nm, exhibited shearing as the dominant deformation mechanism, and this microstructure exhibited the highest strength values. The experimental observations were rationalized based on the theoretically-calculated critical resolved shear stress values for shearing and looping and a modified model for predicting the yield strength for bimodal microstructures was introduced.

Original languageEnglish
Article number146928
JournalMaterials Science and Engineering: A
Volume908
DOIs
StatePublished - Aug 2024

Keywords

  • ATI 718Plus
  • Deformation mechanism
  • Gamma prime
  • Ni-based superalloy
  • Orowan looping
  • Particle-dislocation interaction
  • Shearing

Fingerprint

Dive into the research topics of 'Strengthening mechanisms for microstructures containing unimodal and bimodal γ′ precipitates in ATI 718Plus'. Together they form a unique fingerprint.

Cite this