Stability of High Entropy Alloys to Spinodal Decomposition

Morral, J. E.; Chen, Shuanglin

doi:10.1007/s11669-021-00915-8

Cited by 15 publications

(3 citation statements)

References 22 publications

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“…When a phase becomes locally unstable from a stable or metastable state, its smallest eigenvalue changes from a positive value to negative and others keep positive values unless in some special points such as the cone point of spinodal. [7] After a solvent component is selected, Gibbs energy is a function of compositional variables ðx 1 ; x 2 ; . .…”

Section: Discussionmentioning

confidence: 99%

“…Since this fact is not obvious, a proof of the gauge invariance of the determinant of Gibbs energy Hessian is given in Appendix. However, since the eigenvalues and eigenvectors of Gibbs energy Hessian are gauge variant outside of spinodal, [7] both V and d 3 G dv 3 are gauge variant outside of critical point. As long as U, V, and d 3 G dv 3 are gauge invariant at a critical point, the methods presented above will uniquely determine the critical points as well as the eigenvectors on spinodal.…”

Section: Discussionmentioning

confidence: 99%

“…[3][4][5][6] Our previous paper has a short summary on the study of alloy spinodal decomposition. [7] Reference 7 uses a regular solution model to study the effect of spinodal decomposition on the stability of high entropy alloys. It has shown how miscibility gaps and spinodal curves evolve from binary systems to ternary and higher order systems as well as how they change with temperature.…”

Section: Introductionmentioning

confidence: 99%

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Calculation of Critical Points

Chen

Schmid–Fetzer

Morral

2022

J. Phase Equilib. Diffus.

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Miscibility gaps appear in many alloy systems and, consequently, spinodals and critical points. Three methods are presented for determining a critical point in a multicomponent system. The first method is Gibbs thermodynamic conditions for spinodal and critical point. The spinodal is where the determinant of Gibbs energy Hessian equals zero. The critical point is on the spinodal and where the determinant of another matrix, the Gibbs energy Hessian with any one row replaced by the gradient of the determinant of Gibbs energy Hessian, also equals zero. The second method for a critical point uses the fact that the third directional derivative of the Gibbs energy along the eigenvector direction of Gibbs energy Hessian must be zero at a critical point. The third method uses the geometric features of binodal, spinodal, and eigenvector of Gibbs energy Hessian to determine the position of a critical point on a spinodal curve. The conditions for a spinodal and a critical point in a multicomponent system can be expressed in terms of directional derivatives of Gibbs energy, which are the natural extension of the binary conditions. The ternary Al-Cu-Sn alloy system is used as an example to demonstrate how to apply these conditions to determine the critical points and critical lines. A proof is given in Appendix for the gauge invariance of the determinant of the Gibbs energy Hessian.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Calculation of Critical Points

Chen

Schmid–Fetzer

Morral

2022

J. Phase Equilib. Diffus.

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High-Throughput Design of Multi-Principal Element Alloys with Spinodal Decomposition Assisted Microstructures

Koneru

Kadirvel

2022

J. Phase Equilib. Diffus.

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Thermodynamic Descriptors for Rapid Search of Compositional Complex Spinodal Alloys with Artificial Neural Network

Gong,

Chen,

Shang

et al. 2024

High Entropy Alloys & Materials

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Designing compositional complex alloys with interconnected nanostructures through spinodal decomposition is promising for achieving advanced alloys with exceptional mechanical and functional properties. However, the lack of equilibrium phase diagrams for such compositional complex alloys has posed a significant challenge. In this study, we address this challenge by first introducing data descriptors derived from instability of solid solutions with ideal mixing and later serving as the basis for developing an artificial neural network (ANN) with other commonly used data descriptors. Using this ANN model, we have successfully designed a series of compositional complex spinodal alloys (CCSAs) within the Al–Co–Cr–Fe–Ni and Al–Cu–Fe–Mn–Ni system. Furthermore, we extended the ideal mixing model of solid solution instability by considering chemical short-range ordering and elemental de-mixing, which better explains the elemental separation of CCSAs.

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Stability of High Entropy Alloys to Spinodal Decomposition

Cited by 15 publications

References 22 publications

Calculation of Critical Points

Calculation of Critical Points

High-Throughput Design of Multi-Principal Element Alloys with Spinodal Decomposition Assisted Microstructures

Thermodynamic Descriptors for Rapid Search of Compositional Complex Spinodal Alloys with Artificial Neural Network

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