Sc_{2}Ga_{2}CuO_{7}: A possible Quantum spin liquid near the percolation threshold

TL;DR

This study investigates the magnetic properties of Sc₂Ga₂CuO₇, revealing no magnetic order down to very low temperatures and suggesting it may be a quantum spin liquid near the percolation threshold.

Contribution

The paper provides detailed structural and magnetic characterization of Sc₂Ga₂CuO₇, proposing it as a potential quantum spin liquid due to its disordered magnetic ground state.

Findings

No magnetic long-range order down to 1.5 K

Magnetic specific heat shows a broad maximum at 2.5 K

Power law behavior of specific heat with exponent up to 1.9

Abstract

Sc$_{2}$Ga$_{2}$CuO$_{7}$ (SGCO) crystallizes in a hexagonal structure (space group: $P$$6$$_{3}/mmc$),\textcolor{black}{{} which can be seen as an alternating stacking of single and double triangular layers. Combining neutron, x-ray, and resonant x-ray diffraction we establish that the single triangular layers are mainly populated by non-magnetic Ga$^{3+}$ ions (85\% Ga and 15\% Cu), while the bi-layers have comparable population of Cu$^{2+}$ and Ga$^{3+}$} ions \textcolor{black}{(43\% Cu and 57\% Ga)}. Our susceptibility measurements in the temperature range 1.8 - 400 K give no indication of any spin-freezing or magnetic long-range order (LRO). We infer an effective paramagnetic moment $\mu_{eff}=1.79\pm0.09$ $\mu_{B}$ and a Curie-Weiss temperature $\theta_{CW}$ of about $-44$ K, suggesting antiferromagnetic interactions between the Cu$^{2+}$($S=1/2$) ions. Low-temperature neutron powder diffraction data showed no evidence for LRO down to 1.5 K. In our specific heat data as well, no anomalies were found down to 0.35 K, in the field range 0-140 kOe.\textcolor{black}{{} The magnetic specific heat, $C_{m}$, exhibits a broad maximum at around 2.5 K followed by a nearly power law $C$$_{m}$$\propto$ $T$$^{\alpha}$ behavior at lower temperatures, with $\alpha$ increasing from }0.3\textcolor{black}{{} to} 1.9\textcolor{black}{{} as a function of field for fields upto 90 kOe and then remaining at 1.9 for fields upto 140 kOe. Our results point to a disordered ground state in SGCO. }