Crossover in periodic length dependence of thermal conductivity in 5 d element substituted F e 2 VAl -based superlattices

We investigated the $5d$ element substitution effect on the thermal conductivity in $\\mathrm{F}{\\mathrm{e}}_{2}\\mathrm{VAl}$-based superlattice thin films epitaxially grown on a MgO (100) substrate. We found unique crossover behavior in the period dependences of thermal conductivity for Ta-free $\\mathrm{F}{\\mathrm{e}}_{2}\\mathrm{VAl}$ and $\\mathrm{F}{\\mathrm{e}}_{2}(\\mathrm{V},\\mathrm{Ta})\\mathrm{Al}$-based superlattices. The $\\mathrm{F}{\\mathrm{e}}_{2}(\\mathrm{V},\\mathrm{Ta})\\mathrm{Al}$-based superlattices with periods more than 40 nm appeared to have much lower thermal conductivity than Ta-free $\\mathrm{F}{\\mathrm{e}}_{2}\\mathrm{VAl}$-based superlattices due to the substitution of V by Ta. Unexpectedly, at a shorter periodic length, less than 20 nm, $\\mathrm{F}{\\mathrm{e}}_{2}(\\mathrm{V},\\mathrm{Ta})\\mathrm{Al}$-based superlattices appeared to have higher thermal conductivity than Ta-free $\\mathrm{F}{\\mathrm{e}}_{2}\\mathrm{VAl}$-based superlattices despite such a heavy element substitution by Ta. This surprising experimental fact was well accounted for with theoretical calculations, which predicted the dominant contribution of phonons having a shorter mean free path in the Ta substituted samples.