Non-Fermi liquid behavior with and without quantum criticality in Ce(1-x)Yb(x)CoIn(5)

TL;DR

This study investigates whether non-Fermi liquid behavior in CeCoIn5 is dependent on quantum critical points, finding that such behavior persists even when the quantum critical point is suppressed by Yb doping, suggesting a new state of matter.

Contribution

The paper demonstrates that non-Fermi liquid behavior can exist independently of quantum criticality in CeCoIn5, challenging the traditional view linking the two phenomena.

Findings

Suppression of the QCP has little effect on superconductivity.

Non-Fermi liquid behavior persists without quantum criticality.

Indicates non-Fermi liquid may be a distinct state of matter.

Abstract

One of the greatest challenges to Landau's Fermi liquid theory - the standard theory of metals - is presented by complex materials with strong electronic correlations. In these materials, non-Fermi liquid transport and thermodynamic properties are often explained by the presence of a continuous quantum phase transition which happens at a quantum critical point (QCP). A QCP can be revealed by applying pressure, magnetic field, or changing the chemical composition. In the heavy-fermion compound CeCoIn$_5$, the QCP is assumed to play a decisive role in defining the microscopic structure of both normal and superconducting states. However, the question of whether QCP must be present in the material's phase diagram to induce non-Fermi liquid behavior and trigger superconductivity remains open. Here we show that the full suppression of the field-induced QCP in CeCoIn$_5$ by doping with Yb has surprisingly little impact on both unconventional superconductivity and non-Fermi liquid behavior. This implies that the non-Fermi liquid metallic behavior could be a new state of matter in its own right rather then a consequence of the underlying quantum phase transition.