Two Steps to Improve the Thermoelectric Performance of the CaYbAlInSb System.

A series of quaternary and quinary Zintl phase thermoelectric (TE) compounds, CaYbAlInSb (3.07(1) ≤ ≤ 4.88(2); 0.16(2) ≤ ≤ 2.00), containing Al/In mixed sites as well as Ca/Yb mixed sites has been successfully synthesized by a direct arc-melting method, and the X-ray diffraction analyses indicated that the products initially adopted an orthorhombic BaAlBi-type structure (space group , = 2). However, after a postannealing process at 973 K for 1 month, the particular Yb rich compounds underwent a transformation of the original structure type to a CaGaSb-type phase regardless of the In substitution for Al. The noticeable site preference of cationic Ca and Yb in the three available cationic sites could be understood on the basis of a size match between the central cation and the volume of the anionic polyhedra. The observed phase transition was nicely explained by DFT calculations, proving that the CaGaSb-type phase was energetically more favorable than the BaAlSb-type phase for the particular Yb-rich compound. Moreover, this energy difference between the two title phases was originally the result of both the site energy in the Ca site and the bond energies in the [(Al/In)Sb] anionic building blocks. A series of thermoelectric property data indicated that a two-step process involving a partial/full In substitution for Al and a phase transition from the BaAlSb-type to the CaGaSb-type phase successfully enhanced the electrical conductivities and the Seebeck coefficients of the title compounds. This kind of combined effect eventually resulted in a improvement for the quinary compound CaYbAlInSb by approximately 4 times in comparison to its quaternary predecessor CaYbAlSb.