Large transverse thermoelectric figure of merit in a Dirac semimetal
Junsen Xiang, Sile Hu, Meng Lyu, Wenliang Zhu, Chaoyang Ma, Ziyu Chen,, Frank Steglich, Genfu Chen, and Peijie Sun

TL;DR
This paper demonstrates that the Nernst effect in the Dirac semimetal Cd3As2 yields a high transverse thermoelectric figure of merit, surpassing traditional longitudinal effects, and offers a new pathway for efficient thermoelectric devices.
Contribution
It reveals the potential of the Nernst effect in topological semimetals for high-efficiency thermoelectric applications, highlighting the role of Berry curvature and bipolar transport.
Findings
zNT reaches 0.5 at room temperature in 2 T field
Transverse thermoelectricity surpasses longitudinal effects in this material
Optimization possible via Fermi level tuning and Berry curvature effects
Abstract
Thermoelectric (TE) conversion in conducting materials is of eminent importance for providing renewable energy and solid-state cooling. Although traditionally, the Seebeck effect plays a key role for the TE figure of merit zST, it encounters fundamental constraints hindering its conversion efficiency. Most notably, there are the charge compensation of electrons and holes that diminishes this effect, and the intertwinement of the corresponding electrical and thermal conductivities through the Wiedemann-Franz (WF) law which makes their independent optimization in zST impossible. Here, we demonstrate that in the Dirac semimetal Cd3As2 the Nernst effect, i.e., the transverse counterpart of the Seebeck effect, can generate a large TE figure of merit zNT. At room temperature, zNT = 0.5 in a small field of 2 T; it significantly surmounts its longitudinal counterpart zST for any field and…
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