Reverte Palomino, EduardoCalvo-Dahlborg, MoniqueDahlborg, UlfCampos Gómez, MónicaAlvaredo Olmos, PaulaMartín Rodríguez, PabloGordo Odériz, ElenaCornide Arce, Juan2022-03-152022-03-152021-08Reverte, E., Calvo-Dahlborg, M., Dahlborg, U., Campos, M., Alvaredo, P., Martin-Rodriguez, P., Gordo, E., & Cornide, J. (2021). Design and Production of a New FeCoNiCrAlCu High-Entropy Alloy: Influence of Powder Production Method on Sintering. In Materials (Vol. 14, Issue 15, p. 4342). MDPI AG.1996-1944http://hdl.handle.net/10016/34377The structure of FeCoNiCrAl1.8Cu0.5 high-entropy alloys (HEA) obtained by two different routes has been studied. The selection of the composition has followed the Hume-Rothery approach in terms of number of itinerant electrons (e/a) and average atomic radius to control the formation of specific phases. The alloys were obtained either from a mixture of elemental powders or from gas-atomised powders, being consolidated in both cases by uniaxial pressing and vacuum sin-tering at temperatures of 1200 degrees C and 1300 degrees C. The characterization performed in the sintered samples from both types of powder includes scanning electron microscopy, X-ray diffraction, differential thermal analysis, and density measurements. It was found that the powder production techniques give similar phases content. However, the sintering at 1300 degrees C destroys the achieved phase stability of the samples. The phases identified by all techniques and confirmed by Thermo-Calc calculations are the following: a major Co-Ni-Al-rich (P1) BCC phase, which stays stable after 1300 degrees C sintering and homogenising TT treatments; a complex Cr-Fe-rich (P2) B2 type phase, which transforms into a sigma phase after the 1300 degrees C sintering and homogenising TT treatments; and a very minor Al-Cu-rich (P3) FCC phase, which also transforms into Domain II and Domain III phases during the heating at 1300 degrees C and homogenising TT treatments.17eng© 2021 by the authors. Licensee MDPI, Basel, Switzerland.Atribución 3.0 EspañaAlloy designAtomisationDifferential thermal analysisHigh entropy alloyMicrostructurePowder metallurgyThermo-calcX-Ray diffractionresearch articleIngeniería MecánicaQuímicahttps://doi.org/10.3390/ma14154342open access4342154359Materials (Materials)14AR/0000028922