Hydroflux-Controlled Growth of Magnetic K-Cu-Te-O(H) Phases

Abstract

Innovative synthetic approaches can yield new phases containing novel structural and magnetic motifs. In this work, we show the synthesis and magnetic characterization of three new and one previously reported layered phase in the K-Cu-Te-O(H) phase space using a tunable hydroflux technique. The hydroflux, with a roughly equal molar ratio of water and alkali hydroxide, is a highly oxidizing, low melting solvent which can be used to isolate metastable phases unattainable through traditional solid state or flux techniques. The newly synthesized phases, K2Cu2TeO6, K2Cu2TeO6 · H2O, and K6Cu9Te4O24 · 2 H2O, contain Cu2+ within CuO4 square planar plaquettes and TeO6 octahedra ordering to form structural honeycomb layers isolated by interlayer K+ ions and H2O molecules. We find the synthesized structures display varying tilt sequences of the CuO4 plaquettes, leading to distinct Cu2+ magnetic motifs on the structural honeycomb lattice and a range of effective magnetic dimensionalities. We find that K2Cu2TeO6 · H2O does not order and displays alternating chain Heisenberg antiferromagnetic (AFM) behavior, while K2Cu2TeO6 and K6Cu9Te4O24 · 2 H2O order antiferromagnetically (TN = 100 K and TN = 6.5 K respectively). The previously known phase, K2CuTeO4(OH)2 · H2O, we find contains structurally and magnetically one-dimensional CuO4 plaquettes leading to uniform chain Heisenberg AFM behavior and shows no magnetic order down to T = 0.4 K. We discuss and highlight the usefulness of the hydroflux technique in novel syntheses and the interesting magnetic motifs that arise in these particular phases.