Litcius/Paper detail

Semiconductor-metal transition powers high-efficiency MgAgSb thermoelectrics

Airan Li, Longquan Wang, Xinzhi Wu, Jiankang Li, Xinyuan Wang, Gang Wu, Zhao Hu, Takao Mori

2025Science Advances9 citationsDOIOpen Access PDF

Abstract

Because of the inferior thermoelectric performance of metals, the semiconductor-to-metal transition in thermoelectric materials is always avoided. Here, we demonstrate that α-to-β semiconductor-metal transition in MgAgSb is actually not detrimental but can be strategically exploited to create α/β-MgAgSb junction, enabling 150% enhancement in output power while maintaining high conversion efficiency. This power enhancement lies in the notably reduced internal resistance induced by semiconductor-to-metal transition, which is independent of dimensional changes. Consequently, α/β-MgAgSb can simultaneously achieve high maximum conversion efficiency exceeding 10% (9%) and maximum power density above 1 (0.9) W cm −2 by simulation (experiment), outperforming most p-type materials under identical conditions. In addition, a two-pair thermoelectric module combining α/β-MgAgSb with n-type Mg 3 Sb 0.6 Bi 1.4 achieves an unprecedented power density, representing notable advancements over existing Mg 3 (Sb,Bi) 2 /MgAgSb two-pair system. These findings highlight the immense potential of α/β-MgAgSb for thermoelectric applications and provide insights into the design of high-power thermoelectrics.

Topics & Concepts

Thermoelectric materialsSemiconductorThermoelectric effectMaterials scienceEnergy conversion efficiencyTransition metalOptoelectronicsPower densityThermoelectric generatorEngineering physicsPower (physics)NanotechnologyChemistryPhysicsThermodynamicsBiochemistryCatalysisAdvanced Thermoelectric Materials and DevicesHeusler alloys: electronic and magnetic propertiesThermal Expansion and Ionic Conductivity
Semiconductor-metal transition powers high-efficiency MgAgSb thermoelectrics | Litcius