Low-energy properties of electrons and holes in CuFeS2

The antiferromagnetic semiconductor CuFeS2 belongs to a magnetic symmetry class that is of interest for spintronics applications. In addition, its crystal lattice is compatible with Si, making it possible to integrate it with nonmagnetic semiconducting structures. Therefore, we investigate this material by finding the effective k center dot p Hamiltonian for the electron and hole bands. We base this description on ab initio calculations and classify the electronic bands by their symmetry. As a result, we find that CuFeS2 exhibits spin-polarized bands. We also find that the crystal symmetry allows for the anomalous Hall effect. Finally, we suggest using cyclotron resonance to verify our proposed effective mass tensors at the conduction band minimum and valence band maximum.

Automated summary

The antiferromagnetic semiconductor CuFeS2 is a magnetic material that is compatible with Si, making it suitable for integration with nonmagnetic semiconductors for spintronics applications. Through ab initio calculations and symmetry analysis, we find that CuFeS2 exhibits spin-polarized bands and allows for the anomalous Hall effect. We propose using cyclotron resonance to verify the effective mass tensors at specific band extrema.