A Novel Magnetic Material by Design: Observation of Yb3+ with Spin-1/2 and Possible Superconducting Trace in YbxPt5P

TL;DR

This study reports the discovery of Yb3+ with spin-1/2 in YbxPt5P, a new family of materials, and suggests possible superconductivity at low temperatures, supported by structural, electronic, and resistivity measurements.

Contribution

It introduces a new family of Yb-containing intermetallics with potential superconductivity and provides insights into their electronic structure and magnetic properties.

Findings

Yb3+ with S=1/2 observed at low temperatures

Zero-resistance transition around 0.6 K in Yb0.25Pt5P

First-principles calculations indicate antiferromagnetic ground state

Abstract

The localized f-electrons enrich the magnetic properties in rare-earth-based intermetallics. Among those, compounds with heavier 4d and 5d transition metals are even more fascinating because anomalous electronic properties may be induced by the hybridization of 4f and itinerant conduction electrons primarily from the d orbitals. Here, we describe the observation of trivalent Yb3+ with S = 1/2 at low temperatures in YbxPt5P, the first of a new family of materials. YbxPt5P (0.20< x <1) phases were synthesized and structurally characterized. They exhibit a large homogeneity width with the Yb ratio exclusively occupying the 1a site in the anti-CeCoIn5 structure. Moreover, the resistivity measurement of a sample analyzed as Yb0.25Pt5P shows it to exist a complete zero-resistance transition with a critical transition temperature of ~0.6 K, possible superconductivity. However, the zero-resistivity transition was not observed in YbPt5P with antiferromagnetic ordering existing solely. First-principles electronic structure calculations substantiate the antiferromagnetic ground state and indicate that 2D nesting around the Fermi level may give rise to exotic physical properties, such as superconductivity. YbxPt5P appears to be a unique case among materials.