📝 SummarXiv

Abstract

The challenge of achieving high thermoelectric (TE) performance is mainly from the entanglement among Seebeck coefficient ($S$), electrical conductivity ($\sigma$), and lattice thermal conductivity ($\kappa_{\mathrm{L}}$). In this work, we propose a synergetic strategy of enhancing power factor (PF, $S^2\sigma$) and suppressing $\kappa_{\mathrm{L}}$ by applying a biaxial tensile strain in two silver chalcogenides ScAgSe$_2$ and TmAgTe$_2$ with TlCdS$_2$-type structure. The forbidden $p$-$d$ orbital coupling at the $\Gamma$ point and allowed $p$-$d$ orbital coupling at the A point and the middle of $\Lambda$ line leads to high electronic band dispersion along the $\Gamma$-A direction and a high-degeneracy valence band valley ($\Lambda_2$). The elongation of the Ag-Se bond under tensile strain weakens the orbital coupling between Ag-$d$ and Se/Te-$p$ orbitals and reduces the band energy at the A point, which aligns the valence band and achieving a high band degeneracy. Concurrently, the weaker Ag-Se/Ag-Te bond under a small tensile strain leads to lower phonon group velocity and strong three- and four phonon scatterings, leading to lower $\kappa_{\mathrm{L}}$. Our first-principles calculations combined with electron-phonon coupling analysis as well as phonon and electron Boltzmann transport equations show that applying a 3\% (2\%) tensile strain can enhance the PF along the $c$-axis of ScAgSe$_2$ (TmAgTe$_2$) by 243\% (246\%) at a carrier concentration of 3$\times$10$^{20}$ cm$^{-3}$ and reduce the $\kappa_{\mathrm{L}}$ by 37\% (26\%) at 300 K. Consequently, 2 $\sim$ 4 times of $ZT$ enhancement is obtained by 3\% or 1\% tensile strain in ScAgSe$_2$ (TmAgTe$_2$) at 300 K, achieving a maximum $ZT$ of 3.10 (3.62) at 800 K. Our material design strategy based on molecular orbital analysis reveals an effective route to boosting TE performance, and can be extended to other systems as well.