This repository contains the computational framework and data for exploring compositionally complex alloys through combinatorial mixing. Our initial computational sampling employs a rotationally symmetric compositional contour centred on the equiatomic composition, with a gradient of approximately 5-50 at.% for each element. This methodology samples 69 distinct regions, each representing an individual alloy by its averaged composition and structure. By varying the arrangement of sputtering targets, we substantially expand the sampled compositional space.
We consider the complexity of quinary variants, specifically the
The phase stability of each alloy composition is evaluated using two Gibbs energy construction methods aimed at identifying single-phase FCC regimes. These regimes can be fabricated using either:
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Bulk casting-homogenisation: Conducting a full equilibrium search for a single-phase FCC temperature window between
$900^\circ\text{C}$ and$1300^\circ\text{C}$ . -
Combinatorial thin film: Performing a minimum Gibbs energy search across the compositional space at a lower temperature of
$200^\circ\text{C}$ , comparing FCC with other potential phases.
This repository also calculates solid solution strengthening, leveraging a generalised weak-pinning model that emphasises the statistical fluctuations in solute configurations for enhancing dislocation binding (Varvenne et al.). The methodology employs mechanical elasticity simplification, where solute atoms acting as centres of dilation or contraction introduce volume misfits. Calculations involve factors such as shear yield stress, energy barriers for thermally activated flow, and tensile yield strength at various temperatures and strain rates, utilising data from Pymatgen for modulus, Poisson's ratio, and the TCHEA4 database for molar volume.
