The electronic structure and transport properties of A(5)M(2)Pn(6) (A = Ca, Sr, Ba; M = Ga, Al, In; Pn = As, Sb) are investigated by using the first-principles calculations and Boltzmann transport theory, respectively. The results show that the order of the width of these band gaps is Ca5Ga2As6 (0.37 eV) > Ca5Al2Sb6 (0.35 eV) > Ca5In2Sb6 (0.32 eV) > Sr5In2Sb6 (0.29 eV) > Ba5In2Sb6 (0.27 eV) > Ca5Ga2Sb6 (0.088 eV). For intrinsic A(5)M(2)Pn(6), increasing the band gap is better for improving their thermoelectric properties. For doped A(5)M(2)Pn(6), increasing the band gap is helpful to improve the high-temperature thermoelectric properties of A(5)M(2)Pn(6). However, at 300 K, when the band gap is small enough, regardless of n-type or p-type doping, A(5)M(2)Pn(6) exhibits good thermoelectric properties. Our analysis shows that the band gaps can be roughly adjusted by changing the electronegativity difference between Pn and A, and subtly adjusted by changing the electronegativity difference between Pn and M atoms. So the electronegativity difference among the constituent element is a very important factor affecting the thermoelectric properties.

• 出版日期2014-4-1
• 单位河南大学