Frustrated magnetic planes with intricate interaction pathways in the mineral langite Cu4(OH)6SO4· 2H2O

Abstract

Magnetic and crystallographic properties of the mineral langite Cu4(OH)6SO4· 2H2O are reported. Its layered crystal structure features a peculiar spatial arrangement of spin-12 Cu2+ ions that arises from a combination of corner- and edge-sharing chains. Experimentally, langite orders antiferromagnetically at TN 5.7 K as revealed by magnetization and specific heat measurements. Despite this very low energy scale of the magnetic transition, langite features significantly stronger couplings on the order of 50-70 K. Half of the Cu2+ spins are weakly coupled and saturate around 12T, where the magnetization reaches 0.5μB/Cu. These findings are rationalized by density-functional band-structure calculations suggesting a complex interplay of frustrated exchange couplings in the magnetic planes. A simplified model of coupled magnetic sublattices explains the experimental features qualitatively. To start from reliable structural data, the crystal structure of langite in the 100-280 K temperature range has been determined by single-crystal x-ray diffraction, and the hydrogen positions were refined computationally.