TY - JOUR
T1 - The stability of irradiation-induced defects in Zr3AlC2, Nb4AlC3 and (Zr0.5,Ti0.5)3AlC2 MAX phase-based ceramics
AU - Lambrinou, Konstantza
AU - David, Bowden
AU - Joseph, Ward
AU - Simon, Middleburgh
AU - S., de Moraes Shubeita
AU - E., Zapata-Solvas
AU - Lapauw, Thomas
AU - Vleugels, Jozef
AU - LEE, W.E.
AU - Preuss, M.
AU - Frankel, Philipp
N1 - Score=10
PY - 2020/1/15
Y1 - 2020/1/15
N2 - This work is a first assessment of the radiation tolerance of the nanolayered ternary carbides (MAX phases), Zr3AlC2, Nb4AlC3 and (Zr0.5,Ti0.5)3AlC2, using proton irradiation followed by post-irradiation examination based primarily on x-ray diffraction analysis. These specific MAX phase compounds are being evaluated as candidate coating materials for fuel cladding applications in advanced nuclear reactor systems. The aim of using a MAX phase coating is to protect the substrate fuel cladding material from corrosion damage during its exposure to the primary coolant. Proton irradiation was used in this study as a surrogate for neutron irradiation in order to introduce radiation damage into these ceramics at reactor-relevant temperatures. The post-irradiation examination of these materials revealed that the Zr-based 312-MAX phases, Zr3AlC2 and (Zr0.5,Ti0.5)3AlC2 have a superior ability for defect-recovery above 400 °C, whilst the Nb4AlC3 does not demonstrate any appreciable defect recovery below 600 °C. Density functional theory calculations have demonstrated that the structural differences between the 312 and 413-MAX phase structures govern the variation of the irradiation tolerance of these materials.
AB - This work is a first assessment of the radiation tolerance of the nanolayered ternary carbides (MAX phases), Zr3AlC2, Nb4AlC3 and (Zr0.5,Ti0.5)3AlC2, using proton irradiation followed by post-irradiation examination based primarily on x-ray diffraction analysis. These specific MAX phase compounds are being evaluated as candidate coating materials for fuel cladding applications in advanced nuclear reactor systems. The aim of using a MAX phase coating is to protect the substrate fuel cladding material from corrosion damage during its exposure to the primary coolant. Proton irradiation was used in this study as a surrogate for neutron irradiation in order to introduce radiation damage into these ceramics at reactor-relevant temperatures. The post-irradiation examination of these materials revealed that the Zr-based 312-MAX phases, Zr3AlC2 and (Zr0.5,Ti0.5)3AlC2 have a superior ability for defect-recovery above 400 °C, whilst the Nb4AlC3 does not demonstrate any appreciable defect recovery below 600 °C. Density functional theory calculations have demonstrated that the structural differences between the 312 and 413-MAX phase structures govern the variation of the irradiation tolerance of these materials.
KW - The University of Manchester, School of Materials
KW - Ceramics
KW - Density functional theory (DFT)
KW - x-ray diffraction (XRD)
KW - Lattice strains
UR - http://ecm.sckcen.be/OTCS/llisapi.dll/open/36183698
U2 - 10.1016/j.actamat.2019.10.049
DO - 10.1016/j.actamat.2019.10.049
M3 - Article
SN - 1359-6454
VL - 183
SP - 24
EP - 35
JO - Acta Materialia
JF - Acta Materialia
M1 - 183
ER -