Enhancing the Thermoelectric Performance of GeSb4Te7 Compounds via Alloying Se

Ge-Sb-Te compounds (GST), the well-known phase-change materials, are considered to be promising thermoelectric (TE) materials due to their decent thermoelectric performance. While Ge2Sb2Te5 and GeSb2Te4 have been extensively studied, the TE performance of GeSb4Te7 has not been well explored. Reducing the excessive carrier concentration is crucial to improving TE performance for GeSb4Te7. In this work, we synthesize a series of Se-alloyed GeSb4Te7 compounds and systematically investigate their structures and transport properties. Raman analysis reveals that Se alloying introduces a new vibrational mode of GeSe2, enhancing the interatomic interaction forces within the layers and leading to the reduction of carrier concentration. Additionally, Se alloying also increases the effective mass and thus improves the Seebeck coefficient of GeSb4Te7. The decrease in carrier concentration reduces the carrier thermal conductivity, depressing the total thermal conductivity. Finally, a maximum zT value of 0.77 and an average zT value of 0.48 (300-750 K) have been obtained in GeSb4Te5.5Se1.5. This work investigates the Raman vibration modes and the TE performance in Se-alloyed GeSb4Te7 sheddinglight on the performance optimization of other GST materials.

Automated summary

In this work, a series of Se-alloyed GeSb4Te7 compounds were synthesized and their structures and transport properties were systematically investigated. Raman analysis revealed that Se alloying introduced a new vibrational mode of GeSe2, enhancing the interatomic interaction forces and reducing the carrier concentration. Se alloying also increased the effective mass and improved the Seebeck coefficient of GeSb4Te7. The decrease in carrier concentration reduced the carrier thermal conductivity, resulting in optimized thermoelectric performance.