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Density functional theory (DFT) calculations confirm that the structurally ordered Fe₂VAl Heusler alloy is nonmagnetic narrow-gap semiconductor. This compound easily crystallizes in various disordered phases with high concentration of antisite defects. We study the effect of structural disorder on the electronic structure, magnetic, and electronic transport properties of the full Heusler alloy Fe₂VAl and its off-stoichiometric equivalent Fe₂VAl₁. ₃₅. Data analysis in relation to ab initio calculations indicates an appearance of antisite disorder mainly due to Fe-V and Fe-Al stoichiometric variations. The data for weakly magnetic Fe₂VAl₁. ₃₅ are discussed with respect to Ni₂VAl. Fe₂VAl₁. ₃₅ can be classified as a nearly ferromagnetic metal with a pronounced spin-glassy contribution, which, however, does not have a predominant effect on its thermoelectric properties. The figure of merit ZT is at 300 K about 0. 05 for the Fe sample and 0. 02 for Ni one, respectively. However, it is documented that the narrow d band resulting from Fe/V site exchange can be responsible for the unusual temperature dependencies of the physical properties of the Fe₂TiAl₁. ₃₅ alloy, characteristic of strongly correlated electron systems. As an example, the magnetic susceptibility of Fe₂VAl₁. ₃₅ exhibits singularity characteristic of a Griffiths phase, appearing as an inhomogeneous electronic state below T₆200 K. We also performed numerical analysis which supports the Griffiths phase scenario.
Ślebarski et al. (Mon,) studied this question.