Going step by step is important even under time constraints. Define key requirements: 1) Max operating temperature; 2) mechanical properties (strength, creep); 3) chemical properties (corrosion/oxidation stability in operating environment; 4)thermal conductivity, CTE; 5)manufacturability (source/fabrication); 6) other properties, if needed (optical, magnetic); 7) safety issues. Search database, use AI tools to narrow down to few viable material choice: Metals/ Alloys/Ceramics/polymers/composites. Do simulation (finite element, molecular dynamics, DFT, ) to fine tune device design parameters (size, shape, composition). Build test structures, conduct stress test, narrow down choices. Integrate into device, evaluate functional performance.

First Check the stability of material Then go for their phase identification and crystal structure After that go for their morphological analysis then apply several physical characterization techniques such a VSM Dielectric FTIR Raman..etc.

Define requirements, check material charts, leverage past experience, consult experts, prioritize safety, and ensure availability.

One thing I’ve found helpful is that I must pick up the project that focused on specific missions that costs do not play a critical role in. If the society of scientists accepted me in their environment as a tiny association, I would play a vital role in reaching the destination instead of marketing. Exploring a novel thing is making a new roadmap in unfamiliar lands. Expand, do not play.

Just add to what others have mentioned. In spite of the application, choice of materials and properties, design considerations and fabrication, one should also be mindful of cost implication.

I would quickly define key operating parameters and filter out unsuitable options. I’d focus on proven high-temperature materials like refractory metals, ceramics, or superalloys, considering oxidation resistance and mechanical stability. Computational shortcuts and existing phase diagrams would guide my decision. Practical factors such as cost, manufacturability and availability would refine the choice.

Time constraints are not the ideal circumstances for making decisions. If faced with such limitations, I would opt for the same materials used in a similar-performing product. There is a high likelihood that the engineers behind that product had sufficient time to select the most suitable materials, and I see no reason to reinvent the wheel.

- Évaluer les exigences de l’application, y compris la plage de température et les conditions environnementales. Car l’échelle du matériau (taille allant de nano au macro), et l’environnement dans lequel est ce dernier joue un rôle crucial. Les propriétés des matériaux changent selon ces différents variables, faire plusieurs tests sur plusieurs critères d’utilisation permet un meilleur choix. Merci