Improving the Operational Stability of Thermoelectric Zn4Sb3 by Segmentation

The mixed ionic-electronic conductor beta-Zn4Sb3 is a cheap and high-performing thermoelectric material, but under operating conditions with a temperature gradient and a running current, the material decomposes as Zn readily migrates in the structure. Here, we report an improved stability of beta-Zn(4)Sb(3)by introducing ion-blocking interfaces of stainless steel to segment the sample, produced by a rapid one-step spark plasma sintering synthesis. The stability of the samples is tested under temperature gradients and electric currents, which reveals significantly improved stability of the segmented samples compared to unsegmented samples. The segmented samples are stable under a temperature gradient from 250 degrees C to room temperature with no external current, whereas the unsegmented sample decomposes into ZnSb and Zn under the same conditions. The thermoelectric figure of merit, zT, of the segmented sample is slightly reduced, mainly due to the increased thermal conductivity. In conclusion, a rapid one-step synthesis of segmented beta-Zn4Sb3 is developed, which successfully improves the long-term operational stability by blocking the Zn ion migration.