Abstract
The growth mechanism and synthetic controls for colloidal multinary metal chalcogenide nanocrystals (NCs) involving alkali metals and the pnictogen metals Sb and Bi are unknown. Sb and Bi are prone to form metallic nanocrystals that stay as impurities in the final product. Herein, we synthesize colloidal NaBi(1-x)Sb(x)Se(2-y)S(y) NCs using amine-thiol-Se chemistry. We find that ternary NaBiSe(2) NCs initiate with Bi(0) nuclei and an amorphous intermediate nanoparticle formation that gradually transforms into NaBiSe(2) upon Se addition. Furthermore, we extend our methods to substitute Sb in place of Bi and S in place of Se. Our findings show the initial quasi-cubic morphology transforms into a spherical shape upon increased Sb substitution, and the S incorporation promotes elongation along the <111> direction. We further investigate the thermoelectric transport properties of the Sb-substituted material displaying very low thermal conductivity and n-type transport behavior. Notably, the NaBi(0.75)Sb(0.25)Se(2) material exhibits an ultralow thermal conductivity of 0.25 W·m(-1)·K(-1) at 596 K with an average thermal conductivity of 0.35 W·m(-1)·K(-1) between 358 and 596 K and a ZT(max) of 0.24.