Abstract
Additive manufacturing is increasingly being employed to produce components of complex geometries in structural alloys because of the expected energy savings associated with the near-net-shape capability and the ability to build in novel internal features that are not possible with many conventional manufacturing approaches. However, because of the extreme thermal conditions encountered, the non-equilibrium microstructures produced during powder bed-based additive manufacturing processes must be subjected to custom post-heat treatment processes to recover the target mechanical properties. Phase-field models and simulation techniques have matured to a state where the microstructure evolution paths, and the morphologies of the resulting precipitate phases can be predicted reasonably accurately, considering alloy-specific thermodynamic and kinetic aspects of the nucleation and growth processes. However, phase-field simulations are computationally intensive, which precludes the ability to apply the simulations directly to the length scale of the entire component. Therefore, it is highly desirable to develop low-computational-cost surrogate models that effectively capture the physics at the microstructural length scale, while facilitating the design of optimized processing conditions resulting in location-specific targeted microstructures at the component scale. The work presented here demonstrates the application of the materials knowledge system framework to develop a surrogate model that effectively captures the microstructural path during annealing of a Ni–Mo–Nb alloy containing different Mo and Nb compositions known to segregate during solidification under additive manufacturing conditions. Specifically, the surrogate model built in this work is based on a Gaussian process autoregressive model informed by statistical representation of simulated microstructures using two-point correlations and dimensionality reduction through principal component analysis. This surrogate model is shown to capture the bifurcation of the microstructural path during precipitation, which yields a microstructure dominated by the γ′′ phase at high Nb concentrations and the δ phase at low Nb concentrations.
Original language | English |
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Pages (from-to) | 4863-4881 |
Number of pages | 19 |
Journal | Journal of Materials Science |
Volume | 59 |
Issue number | 12 |
DOIs | |
State | Published - Mar 2024 |
Funding
This research was partially supported by the Exascale Computing Project (17-SC-20-SC), a collaborative effort of the U.S. DOE Office of Science and the National Nuclear Security Administration at the Oak Ridge National Laboratory. This research used resources of the Oak Ridge Leadership Computing Facility, which is a DOE Office of Science User Facility supported under contract DE- AC05-00OR22725. SK acknowledges support from NSF 2119640. The authors acknowledge drawing inspiration from the many research works of Prof. Zbib, and are grateful for the opportunity to submit our work to the special issue honouring him.
Funders | Funder number |
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National Nuclear Security Administration | |
National Science Foundation | |
Oak Ridge National Laboratory | |
U.S. Department of Energy | |
Office of Science | DE- AC05-00OR22725 |
Office of Science |