CeFe2Al10: A correlated metal with a Fermi surface exhibiting nonmetallic conduction

Metals can be defined as materials with a Fermi surface or as materials exhibiting metallic conduction (i.e., d rho/dT > 0). Usually, these definitions both hold at low temperatures, such as liquid-helium temperatures, as the Fermi energy is sufficiently larger than the thermal energy. However, they may not both hold in correlated electron systems where the Fermi energy is reduced by renormalization. In this paper, we demonstrate that although the resistivity of CeFe2Al10 increases with decreasing temperature below similar to 20 K, CeFe2Al10 is a metal with a Fermi surface. This assertion is based on the observation of Shubnikov-de Haas oscillations and a Hall resistivity that changes sign with the magnetic field, which requires the coexistence of electron and hole carriers. Our analysis of Shubnikov-de Haas and magnetotransport data indicates that the Fermi energies are as small as similar to 30 K and that, despite the increasing carrier mobility with decreasing temperature as in conventional metals, the loss of thermally excited carriers leads to nonmetallic conduction below similar to 20 K. Furthermore, we investigate how this anomalous metal transforms to a more conventional metal with metallic conduction with the application of high pressure and a high magnetic field.

Automated summary

This paper investigates a material composed of CeFe2Al10, which exhibits metallic conduction despite an increase in resistivity with decreasing temperature below 20K.