RT Journal Article
T1 Fabrication and characterization of Cu reinforced with Y-enriched particles following a novel powder metallurgy route
A1 Muñoz, A.
A1 Savoini, B.
A1 Monge, M. A.
A1 Ortega Villafuerte, Yanicet
A1 Durá, O. J.
AB Dispersion strengthened copper alloys have been produced following an innovative powder metallurgy route. Copper and yttrium acetate powders have been mechanically alloyed and posteriorly thermal treated at 923 K for 3 h and 15 h under a hydrogen atmosphere in order to transform the yttrium acetate into Y_2O_3. Subsequently, the powders were consolidated by hot isostatic pressing. It has been concluded that the duration of the thermal treatment of the powder is a determining factor in the degree of densification of the alloy. The study of the microstructure by Scanning Electron Microscopy and Electron Backscatter Diffraction has revealed the presence of micrometer and submicrometer grains and nanometric Y-O enriched Cu particles embedded in the copper matrix, the mean grain size being smaller for the sample produced from the powder thermal treated for 15 h. Transmission Electron Microscopy investigations concluded that the nanoparticles exhibit a spherical shape with a size up to 25 nm and correspond to monoclinic Y_2O_3. Annealing twins have been also observed, especially in the material produced from thermal treated powder for longer. The mechanical properties have been inferred from Vickers microhardness measurements and compression tests. Below 473 K the yield strengths of the produced materials are greater than that of pure copper and above 473 K are close to them. From the study of the thermal properties of the densest material it has been found that its thermal conductivity remains nearly constant in the temperature range 300-773 K, and its value is around 85% the thermal conductivity of CuCrZr, the reference material for ITER.
PB Elsevier
SN 2352-1791
YR 2021
FD 2021-12
LK https://hdl.handle.net/20.500.14352/4490
UL https://hdl.handle.net/20.500.14352/4490
LA eng
NO ©2021 ElsevierThe present work has been supported by the Agencia Estatal de Investigaci ' on (PID2019-105325RB-C33/AEI/10.13039/501100011033) and by the Regional Government of Madrid through the program TECHNOFUSION(III)CM (S2018/EMT-4437). The support of the Regional Government of Madrid through the multi-annual agreement with UC3M ("Excelencia para el Profesorado Universitario" EPUC3M14) -Fifth regional research plan 2016-2020 is acknowledge.
NO Ministerio de Ciencia e Innovación (MICINN)
NO Comunidad de Madrid
DS Docta Complutense
RD 13 abr 2025