Exploring Low-Dimensional Magnetism in Cobalt Vanadates, ACoV2O7~(A~=~Ca, Sr) : Crystal Growth and Magnetic Properties of Effective Spin-1/2 Zigzag Chains

Abstract

We report the successful growth of high-quality single crystals of , a quasi-one-dimensional zigzag chain compound containing Co2+ ions, using the optical floating zone method. The crystal growth was stabilized under high-pressure argon-oxygen gas with slow growth rates, overcoming challenges associated with the incongruent melting behavior of this material. X-ray diffraction confirms the zigzag arrangement of Co2+ ions, forming a quasi-one-dimensional chain structure. Magnetic susceptibility and heat capacity measurements reveal an antiferromagnetic phase transition at the N\'eel temperature (TN 3.5 K) and negative Curie-Weiss temperatures, indicative of dominant antiferromagnetic interactions. The distorted CoO6 octahedral geometry and strong spin-orbit coupling suggest that Co2+ ions likely exhibit an effective J = 1/2 Kramers doublet state. The results presented here demonstrate the potential of \ as a platform for investigating low-dimensional magnetism and quantum magnetic phenomena. These insights shed light on the role of the A-site ion in tuning the magnetic interactions, which will foster future research into the field-induced behavior in these cobalt vanadates.