Transverse and Longitudinal Magnetothermopower Promoted by Ambipolar Effect in Half-Heusler Topological Materials

Abstract

Topologically trivial and non-trivial semimetals with a high degree of carrier compensation are well known for demonstrating large transverse magnetothermopower (Syx). However, in such systems, the longitudinal magnetothermopower (Sxx) is typically suppressed due to nearly perfect electron-hole compensation. Here, we show that the half-Heusler topological semimetal DyPtBi exhibits simultaneously large Sxx and Syx magnetothermopowers, defying this conventional trade-off. In B=14\,T, thermopower of DyPtBi reaches peak values of Sxx=131\,μV/K at T=149\,K and Syx=-297\,μV/K at T=200\,K, and transverse component remains significantly large even at 290\,K (Syx=-213\,μV/K). Remarkably, at T=290\,K and in relatively weak magnetic field of 1\,T, both relevant for practical applications, DyPtBi shows Syx=-18\,μV/K, which is one of the largest values reported under such conditions. The large transverse thermopower originates from an ambipolar effect associated with thermal excitation occurring in zero-gap semiconductors. Due to the imperfect electron-hole compensation, an intrinsic asymmetry between hole- and electron-type carriers enables pronounced values of both Sxx and Syx, resulting in high effective thermopower (Sxx+|Syx|=379\,μV/K) in DyPtBi at 200\,K. A comparative analysis with DyPdBi, another half-Heusler material that demonstrates large Sxx=123\,μV/K but small Syx=-16\,μV/K (both values obtained at T=293\,K and B=14\,T), highlights the critical role of band structure and compensation tuning. These findings underscore the potential of chemical doping and band engineering in rare-earth-based half-Heusler materials for optimizing both transverse and longitudinal thermoelectric properties.

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