Los puntos clave no están disponibles para este artículo en este momento.
Solid-state thermoelectric coolers, which enable direct heat pumping by utilizing electricity, play an essential role in electronic refrigeration. Given that these devices usually cool down to the sub-ambient temperature range, their performance is critically dependent on the material properties at temperatures below 300 K. Consequently, enhancing the thermoelectric properties of materials at sub-ambient temperature is of paramount importance for advancing cooling technology. Herein, a single-crystalline Mg3Bi2-based material has been prepared and exhibits high electron mobility. As a result, thermoelectric figure-of-merit values of ∼1.05 at 300 K and ∼0.87 at 250 K (along the ab plane) have been achieved, which are superior to commercial n-type Bi2(Te, Se)3. Thermoelectric coolers (single- and double-stage devices) based on the n-type single-crystalline Mg3Bi1.497Sb0.5Te0.003 and p-type (Bi, Sb)2Te3 have been fabricated. The double-stage cooler demonstrates a remarkable maximum cooling temperature difference of ∼106.8 K at the hot-side temperature of 350 K, surpassing the performance of commercial Bi2Te3-based devices. Notably, the Mg3Bi2-based double-stage device exhibits exceptional cyclic stability, maintaining its cooling performance without any observable degradation after approximately 2,000 cycles between the input currents of 1 and 3 A. These findings show that single-crystalline Mg3Bi2 alloys hold great promise for thermoelectric cooling applications.
Ma et al. (Wed,) studied this question.
Synapse has enriched 5 closely related papers on similar clinical questions. Consider them for comparative context: