We show an example of hierarchically designing electronic bands of PbSe toward excellent thermoelectric performance. We find that alloying 15 mol % PbTe into PbSe causes a negligible change in the light and heavy valence band energy offsets (Δ E) of PbSe around room temperature; however, with rising temperature it makes Δ E decrease at a significantly higher rate than in PbSe. In other words, the temperature-induced valence band convergence of PbSe is accelerated by alloying with PbTe. On this basis, applying 3 mol % Cd substitution on the Pb sites of PbSeTe decreases Δ E and enhances the Seebeck coefficient at all temperatures. Excess Cd precipitates out as CdSeTe , whose valence band aligns with that of the p-type Na-doped PbSeTe matrix. This enables facile charge transport across the matrix/precipitate interfaces and retains the high carrier mobilities. Meanwhile, compared to PbSe the lattice thermal conductivity of PbSeTe is significantly decreased to its amorphous limit of 0.5 W m K. Consequently, a highest peak ZT of 1.7 at 900 K and a record high average ZT of ∼1 (400-900 K) for a PbSe-based system are achieved in the composition PbNaCdSeTe, which are ∼70% and ∼50% higher than those of PbNaSe control sample, respectively.
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