Pressure-induced unusual metallic state in EuNiO3

Abstract

The perovskite antiferromagnetic (T N 220 K) insulator EuNiO3 undergoes at ambient pressure a metal-to-insulator transition at T MI = 460 K which is associated with a simultaneous orthorhombic-to-monoclinic distortion, leading to charge disproportionation. We have investigated the change of the structural and magnetic properties of EuNiO3 with pressure (up to 20 GPa) across its quantum critical point (QCP) using low-temperature synchrotron angle-resolved x-ray diffraction and 151Eu nuclear forward scattering of synchrotron radiation, respectively. With increasing pressure we find that after a small increase of T N (p ≤ 2 GPa) and the induced magnetic hyperfine field B hf at the 151Eu nucleus (p ≤ 9.7 GPa), both T N and B hf are strongly reduced and finally disappear at p c 10.5 GPa, indicating a magnetic QCP at p c. The analysis of the structural parameters up to 10.5 GPa reveals no change of the lattice symmetry within the experimental resolution. Since the pressure-induced insulator-to-metal transition occurs at p IM 6 GPa, this result implies the existence of an antiferromagnetic metallic state between 6 and 10.5 GPa. We further show from the analysis of the reported high pressure electrical resistance data on EuNiO3 at low-temperatures that in the vicinity of the QCP the system behaves as non-Fermi-liquid, with the resistance changing as T n, with n=1.6, whereas it becomes a normal Fermi-liquid, n = 2, for pressures above 15 GPa. On the basis of the obtained data a magnetic phase diagram in the (p, T) space is suggested.