As an ecofriendly and low-cost thermoelectric material, Cu2SnSe3 has recently drawn much attention. In this work, the thermoelectric properties of Cu2SnSe3-based materials have been synergistically optimized. Ag doping at the Cu site enables strong phonon scattering via large strain field fluctuations and increases the effective mass of carriers through band engineering, which results in a reduced lattice thermal conductivity and enhanced Seebeck coefficient. Thus, a peak ZT value of 1.04 at 800 K is obtained for Cu1.85Ag0.15SnSe3. Then, In is further doped at the Sn site to further increase the carrier concentration and power factor; the ZT values of Cu1.85Ag0.15Sn1-yInySe3 samples are highly improved in the temperature range of 300-800 K, and a peak ZT value of 1.12 is obtained at 800 K for the Cu1.85Ag0.15Sn0.91In0.09Se3 sample. Considering that Ag2S decomposes to Ag and S completely under vacuum and high current field, the sulfur vapor would be pumped away by a vacuum pump, and the generated Ag not only enriches at the grain boundary of the Cu1.85Ag0.15Sn0.91In0.09Se3 bulk material but also enters the matrix and occupies the Cu site, leading to the extruding Cu and Se forming the second phase of CuSe nanoparticles. Thus, the power factor greatly improves to 13.8 μW cm-1 K-2 at 700 K, and the lattice thermal conductivity is as low as 0.12 W m-1 K-1 at 800 K for the Cu1.85Ag0.15Sn0.91In0.09Se3/4% Ag2S composite. Finally, a high ZT value of 1.58 is obtained at 800 K for the Cu1.85Ag0.15Sn0.91In0.09Se3/4% Ag2S composite, which is nearly an increase of 204% compared to that of Cu2SnSe3. This work provides an effective solution to optimize the conflicting material properties for Cu2SnSe3-based thermoelectric materials.
Keywords: Ag2S; Cu2SnSe3; interface scattering; self-propagating high-temperature synthesis; thermoelectric.