Long-range magnetic order in the anisotropic triangular lattice system CeCd3As3

Abstract: We report the physical properties of $R$Cd${3}$As${3}$ ($R$ = La and Ce) compounds, crystallized into a hexagonal ScAl${3}$C${3}$-type structure ($P$6${3}$/mmc) such that the $R$ sublattice forms a spin-orbit coupled triangular lattice. Magnetic susceptibility measurements indicate the 4$f$ electrons of Ce$^{3+}$ ions are well localized and reveal a large magnetic anisotropy. The electrical resistivity and specific heat measurement for $R$Cd${3}$As${3}$ exhibit an anomaly at high temperatures ($T{0}$ $\sim$ 63 K for $R$ = La and $T_{0}$ $\sim$ 136 K for $R$ = Ce), most likely due to a structural transition. Specific heat measurements for CeCd${3}$As${3}$ clearly indicate a long range magnetic order below $T_{N}$ = 0.42 K. Although the magnetic contribution to the specific heat $C_{m}/T$ increases significantly below $\sim$ 10 K, the electrical resistivity for CeCd${3}$As${3}$ follows typical, metallic behavior inconsistent with Kondo lattice systems. In CeCd$3$As$_3$ only $\sim$ 40 $\%$ of the $R \ln(2)$ magnetic entropy is recovered by $T_N$ and the $R$ln(2) entropy is fully achieved at about the Curie-Weiss temperature $|\theta{p}|$. Unusually, based on our current investigations, the magnetic specific heat below $|\theta_{p}|$ is not attributed to a Kondo contribution, but rather associated with the magnetic ordering and frustration on the triangular lattice. Specific heat measurements in applied magnetic field show a negligible variation of $T_{N}$ for $H \parallel c$, whereas a suppression of $T_{N}$ is observed above 40 kOe for $H \parallel ab$. Such behavior is consistent with the application a magnetic field within the $ab$-plane breaking the triangular symmetry and partially relieving the magnetic frustration in this system.