Giant anomalous Nernst signal in the antiferromagnet YbMnBi2

A large anomalous Nernst effect (ANE) is crucial for thermoelectric energy conversion applications because the associated unique transverse geometry facilitates module fabrication. Topological ferromagnets with large Berry curvatures show large AN Es; however, they face drawbacks such as strong magnetic disturbances and low mobility due to high magnetization. Herein, we demonstrate that YbMnBi2, a canted antiferromagnet, has a large ANE conductivity of similar to 10 A m(-1) K-1 that surpasses large values observed in other ferromagnets (3-5 A m(-1) K-1). The canted spin structure of Mn guarantees a non-zero Berry curvature, but generates only a weak magnetization three orders of magnitude lower than that of general ferromagnets. The heavy Bi with a large spin-orbit coupling enables a large ANE and low thermal conductivity, whereas its highly dispersive P-x/y orbitals ensure low resistivity. The high anomalous transverse thermoelectric performance and extremely small magnetization make YbMnBi2 an excellent candidate for transverse thermoelectrics.

Automated summary

YbMnBi2, a canted antiferromagnet, demonstrates a large anomalous Nernst effect (ANE) conductivity, making it a promising candidate for thermoelectric energy conversion applications. Its unique structure guarantees a large ANE and significantly lower magnetization compared to general ferromagnets.