Investigation on High-Temperature Thermoelectric Characteristics of β-Ga2O3

The majority of waste heat sources are industrial steel and automobile where the operating temperature is higher than 673 K. However, the development of the thermoelectric (TE) field is still limited by low operating temperature, high-cost raw materials, and unstable device performance. beta-Ga2O3 is endowed with nontoxic, eco-friendly, low-cost, and thermal stability advantages, which may be a potential high-temperature oxide thermoelectric material. Here, the capacitance-voltage (C-V) measurements and phonon-dominant thermal transport mechanism of beta-Ga2O3 are revealed at first; lower lattice thermal conductivity of beta-Ga2O3 will be obtained at a higher test temperature. Additionally, the electrical transport properties of beta-Ga2O3 are further demonstrated by Seebeck coefficient and electrical conductivity at the segmented temperature range (323 similar to 523 K; 873 similar to 1073 K), indicating that regulation of carrier concentration is effective to optimize the TE performance. The maximum ZT of 0.237 is obtained for the sample with N-D = 6.1 x 10(18) cm(-3) at 1073 K, whose increase is more than twice than that of another sample with N-D = 5.7 x 10(17) cm(-3). As a result, beta-Ga2O3 may be a promising candidate for high-temperature TE materials, which possesses great operating stability and durability in a harsh environment, especially for application scenarios where stability and performance are equally important.