Heat treatment and composition optimization of nanoprecipitation hardened alloys
Heat treatment and composition optimization of nanoprecipitation hardened alloys
A modeling strategy for designing nanoprecipitation strengthened alloys is presented here. This work summarises the application of a new thermokinetics approach wherein multiple design criteria are enforced: corrosion resistance and high strength combined with affordable thermomechanical processing schedules. The methodology presented here iteratively performs thermodynamic and kinetic calculations, which are aimed at determining the best precipitate nanostructures following multiple design objectives. A genetic algorithm is employed to more rapidly find optimal alloy compositions and processing parameters consistent with the design objectives. The strength was maximized, while conditions on the microstructure were imposed: corrosion resistance, fine martensite formation, and the prevention of primary and undesirable precipitate particles. It is possible to computationally design new alloys strengthened by Ni-based nanoprecipitates and carbides with yield strengths exceeding 1.6GPa and good corrosion resistance. A major limitation in the methodology is the determination of optimum processing times, which require the computation of the formation energies of non-equilibrium precipitates employing other techniques. A method to circumvent this limitation is discussed.
Alloy design, Genetic algorithms, Kinetics, Thermodynamics
375-381
Rivera-Diaz-Del-Castillo, Pedro E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
Xu, W.
ee9701c4-ccf9-41b7-9cb9-d5a2e160b5e2
Rivera-Diaz-Del-Castillo, Pedro E.J.
6e0abc1c-2aee-4a18-badc-bac28e7831e2
Xu, W.
ee9701c4-ccf9-41b7-9cb9-d5a2e160b5e2
Rivera-Diaz-Del-Castillo, Pedro E.J. and Xu, W.
(2011)
Heat treatment and composition optimization of nanoprecipitation hardened alloys.
Materials and Manufacturing Processes, 26 (3), .
(doi:10.1080/10426914.2011.567118).
Abstract
A modeling strategy for designing nanoprecipitation strengthened alloys is presented here. This work summarises the application of a new thermokinetics approach wherein multiple design criteria are enforced: corrosion resistance and high strength combined with affordable thermomechanical processing schedules. The methodology presented here iteratively performs thermodynamic and kinetic calculations, which are aimed at determining the best precipitate nanostructures following multiple design objectives. A genetic algorithm is employed to more rapidly find optimal alloy compositions and processing parameters consistent with the design objectives. The strength was maximized, while conditions on the microstructure were imposed: corrosion resistance, fine martensite formation, and the prevention of primary and undesirable precipitate particles. It is possible to computationally design new alloys strengthened by Ni-based nanoprecipitates and carbides with yield strengths exceeding 1.6GPa and good corrosion resistance. A major limitation in the methodology is the determination of optimum processing times, which require the computation of the formation energies of non-equilibrium precipitates employing other techniques. A method to circumvent this limitation is discussed.
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Accepted/In Press date: 20 February 2011
e-pub ahead of print date: 11 April 2011
Keywords:
Alloy design, Genetic algorithms, Kinetics, Thermodynamics
Identifiers
Local EPrints ID: 492719
URI: http://eprints.soton.ac.uk/id/eprint/492719
ISSN: 1042-6914
PURE UUID: a0eda641-f849-4f2a-acb2-326084e3cb72
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Date deposited: 13 Aug 2024 16:31
Last modified: 14 Aug 2024 02:07
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Contributors
Author:
Pedro E.J. Rivera-Diaz-Del-Castillo
Author:
W. Xu
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