Interplay of short-range bond order and A-type antiferromagnetic order in metallic triangular lattice GdZn3P3

Abstract

We investigate a hexagonal ScAl3C3-type antiferromagnet GdZn3P3 single crystal. Compared with antiferromagnetic topological material EuM2X2 (M=Zn, Cd; X=P, As), the GdZn3P3 features an additional ZnP3 trigonal planar units. Notably, single-crystal X-ray diffraction analysis reveals that Zn and P atoms within trigonal planar layer exhibit significant anisotropic displacement parameters with a space group of P63/mmc. Meanwhile, scanning transmission electron microscopy experiment demonstrates the presence of interstitial P atoms above and below the ZnP honeycomb lattice, suggesting potential ZnP bond instability within the ZnP3 trigonal layers. Concerning the triangular Gd3+ layer, the magnetic susceptibility (T) and heat capacity measurements reveal long-range antiferromagnetic order at TN = 4.5 K. Below TN, the in-plane (T) is nearly 4 times the (T) along c axis, indicative of strong magnetic anisotropy. The Curie Weiss fitting to the low temperature (T) data reveals ferromagnetic interaction (θCW = 5.2 K) in ab-plane, and antiferromagnetic interaction (θCW = -1 K) along c axis, suggesting the ground state as an A-type antiferromagnetic order. Correspondingly, the density function theory calculation shows that GdZn3P3 is an indirect semiconductor with a band gap 0.27 eV, supported by the resistivity measurement on polycrystal sample. Interestingly, the GdZn3P3 single crystal exhibits metallic conductivity with an anomaly at TN, likely associated with the observation of interstitial P atoms mentioned above. Therefore, our results establish GdZn3P3 system as a concrete example for investigating the coupling between charge carrier and triangular lattice magnetism in the two-dimensional lattice framework, on the background of short-range bond order.