Lattice misfit design and characterisation in BCC superalloys

Kan Ma; Sibo Cheng; Xianfeng Ma; Thomas Blackburn; Alexander J. Knowles; Ke An; Javier Santisteban; Fan Sun; Christopher H. Zenk; Pedro A. Ferreirós

doi:10.1016/j.scriptamat.2025.116802

Lattice misfit design and characterisation in BCC superalloys

Kan Ma
, Sibo Cheng
, Xianfeng Ma
, Thomas Blackburn
, Alexander J. Knowles
, Ke An
, Javier Santisteban
, Fan Sun
, Christopher H. Zenk
, Pedro A. Ferreirós

Materials Engineering

Research output: Contribution to journal › Article › peer-review

9 Scopus citations

Abstract

BCC superalloys are a promising class of high-temperature materials with a wide range of lattice misfit values, ranging from near-zero to ∼8 %. Analogous to nickel superalloys, lattice misfit combined with elastic anisotropy dictates precipitate morphology (spherical, cuboidal, plate/needle-like), coarsening kinetics, strengthening mechanisms, and microstructure evolution, making misfit control critical for tailoring microstructural stability and creep resistance. However, misfit characterisation, especially at high temperatures, is still in its infancy to establish its links with mechanical properties. This perspective emphasises three aspects of BCC superalloys: representative misfit-driven microstructures and temperature-dependent misfit evolution, state-of-the-art diffraction techniques for high-temperature misfit quantification, and machine learning frameworks to accelerate alloy design involving misfit. By consolidating diverse misfit data and advanced characterisation/modelling strategies, we outline strategies to bridge computational and experimental gaps, advocating for physics-informed models and high-throughput techniques to design next-generation BCC superalloys and motivate systematic studies on the misfit-property relationship in this nascent material class.

Original language	English
Article number	116802
Journal	Scripta Materialia
Volume	267
DOIs	https://doi.org/10.1016/j.scriptamat.2025.116802
State	Published - Oct 1 2025

Funding

This project has received funding from European Union's Horizon 2020 research and innovation programme under grant agreement No 958418 “COMPASsCO2” ( https://www.compassco2.eu). A.J. Knowles acknowledges support from: UKRI Future Leaders Fellowship (MR/T019174/1) and Royal Academy of Engineering Research Fellowship (RF\201819\18\158). K. Ma and A.J. Knowles acknowledge the Diamond Light Source (United Kingdom) for time on beamline I11 under proposal CY32708. A portion of this research used resources at the Spallation Neutron Source, a DOE Office of Science User Facility operated by the Oak Ridge National Laboratory. The beam time was allocated to BL-7 Vulcan on proposal number IPTS-23066 This project has received funding from European Union’s Horizon 2020 research and innovation programme under grant agreement No 958418 “COMPASsCO2” ( https://www.compassco2.eu ). A.J. Knowles acknowledges support from: UKRI Future Leaders Fellowship (MR/T019174/1) and Royal Academy of Engineering Research Fellowship (RF\201819\18\158). K. Ma and A.J. Knowles acknowledge the Diamond Light Source (United Kingdom) for time on beamline I11 under proposal CY32708. A portion of this research used resources at the Spallation Neutron Source, a DOE Office of Science User Facility operated by the Oak Ridge National Laboratory. The beam time was allocated to BL-7 Vulcan on proposal number IPTS-23066

Keywords

Anisotropy
BCC superalloys
Crystallography
Diffraction
Lattice misfit

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10.1016/j.scriptamat.2025.116802

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title = "Lattice misfit design and characterisation in BCC superalloys",

abstract = "BCC superalloys are a promising class of high-temperature materials with a wide range of lattice misfit values, ranging from near-zero to ∼8 \%. Analogous to nickel superalloys, lattice misfit combined with elastic anisotropy dictates precipitate morphology (spherical, cuboidal, plate/needle-like), coarsening kinetics, strengthening mechanisms, and microstructure evolution, making misfit control critical for tailoring microstructural stability and creep resistance. However, misfit characterisation, especially at high temperatures, is still in its infancy to establish its links with mechanical properties. This perspective emphasises three aspects of BCC superalloys: representative misfit-driven microstructures and temperature-dependent misfit evolution, state-of-the-art diffraction techniques for high-temperature misfit quantification, and machine learning frameworks to accelerate alloy design involving misfit. By consolidating diverse misfit data and advanced characterisation/modelling strategies, we outline strategies to bridge computational and experimental gaps, advocating for physics-informed models and high-throughput techniques to design next-generation BCC superalloys and motivate systematic studies on the misfit-property relationship in this nascent material class.",

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author = "Kan Ma and Sibo Cheng and Xianfeng Ma and Thomas Blackburn and Knowles, \{Alexander J.\} and Ke An and Javier Santisteban and Fan Sun and Zenk, \{Christopher H.\} and Ferreir{\'o}s, \{Pedro A.\}",

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AU - An, Ke

AU - Santisteban, Javier

AU - Sun, Fan

AU - Zenk, Christopher H.

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N2 - BCC superalloys are a promising class of high-temperature materials with a wide range of lattice misfit values, ranging from near-zero to ∼8 %. Analogous to nickel superalloys, lattice misfit combined with elastic anisotropy dictates precipitate morphology (spherical, cuboidal, plate/needle-like), coarsening kinetics, strengthening mechanisms, and microstructure evolution, making misfit control critical for tailoring microstructural stability and creep resistance. However, misfit characterisation, especially at high temperatures, is still in its infancy to establish its links with mechanical properties. This perspective emphasises three aspects of BCC superalloys: representative misfit-driven microstructures and temperature-dependent misfit evolution, state-of-the-art diffraction techniques for high-temperature misfit quantification, and machine learning frameworks to accelerate alloy design involving misfit. By consolidating diverse misfit data and advanced characterisation/modelling strategies, we outline strategies to bridge computational and experimental gaps, advocating for physics-informed models and high-throughput techniques to design next-generation BCC superalloys and motivate systematic studies on the misfit-property relationship in this nascent material class.

AB - BCC superalloys are a promising class of high-temperature materials with a wide range of lattice misfit values, ranging from near-zero to ∼8 %. Analogous to nickel superalloys, lattice misfit combined with elastic anisotropy dictates precipitate morphology (spherical, cuboidal, plate/needle-like), coarsening kinetics, strengthening mechanisms, and microstructure evolution, making misfit control critical for tailoring microstructural stability and creep resistance. However, misfit characterisation, especially at high temperatures, is still in its infancy to establish its links with mechanical properties. This perspective emphasises three aspects of BCC superalloys: representative misfit-driven microstructures and temperature-dependent misfit evolution, state-of-the-art diffraction techniques for high-temperature misfit quantification, and machine learning frameworks to accelerate alloy design involving misfit. By consolidating diverse misfit data and advanced characterisation/modelling strategies, we outline strategies to bridge computational and experimental gaps, advocating for physics-informed models and high-throughput techniques to design next-generation BCC superalloys and motivate systematic studies on the misfit-property relationship in this nascent material class.

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KW - Crystallography

KW - Diffraction

KW - Lattice misfit

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Lattice misfit design and characterisation in BCC superalloys

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