Despite having never been synthesized, the MAX phase Zr 2 AlC attracts a lot of interest owing to its foreseen properties. A possible way to circumvent this obstacle is to stabilize Zr 2 AlC by partially substituting one of its constituting elements. Here we report on attempts to synthesise quaternary MAX phases (Zr,M) 2 AlC and Zr 2 (Al,A)C where M = Cr, Ti or Mo and A = S, As, Sn, Sb and Pb. We were notably able to produce Zr 2 (Al 0. IntroductionThe MAX phases are a family of carbides and nitrides crystallizing with the hexagonal P6 3 /mmc structure in the general formula M n+1 AX n with n being an integer, M being an early transition metal, A being a group 13-16 element and X being C and/or N.[1] Around 70 ternary MAX phases can be synthesized as a bulk phase. More than half of known MAX phases with n = 1 were first reported in the 1960s by Nowotny et al. [2] and named 'H-phases'. They were almost completely ignored for two decades until Barsoum and El-Raghy renewed interest in 1996 by reporting the remarkable properties of Ti 3 SiC 2 ,[3] then demonstrating these properties were shared by the other MAX phases [4,5] and by finally defining the current 'MAX phase' appellation and definition.[6] Owing to their structure consisting of the stacking of n 'ceramic' layer(s) of MX interleaved by an A 'metallic' plane, MAX phases show a combination of both ceramic and metallic features (high thermal shock resistance, good machinability and high thermal and electrical conductivities, alike most metals; high decomposition or melting temperature, high elastic stiffness, and high oxidation and corrosion resistance as