Magnetosynthesis effect on the structure and ground state of Cu2+-based antiferromagnets
Abstract
Subtle synthetic variables can have an outsizes influence on the crystal structure and magnetic properties of a material, particularly those of quantum materials. In this work, we investigate the impact of synthesis under a magnetic field (magnetosynthesis) on the crystal structure and magnetic properties of several Cu2+ (S=1/2) based materials with antiferromagnetic interactions and varying levels of magnetic frustration, from simple antiferromagnets to a quantum spin liquid. We employ small (0.09 - 0.37 T) magnetic fields applied during low-temperature hydrothermal or evaporative synthesis of the simple antiferromagnet CuCl2·2H2O, the canted antiferromagnet (Cu,Zn)3Cl4(OH)2·2H2O, the frustrated and canted antiferromagnet atacamite Cu2(OH)3Cl, and the highly frustrated quantum spin liquid herbertsmithite Cu3Zn(OH)6Cl2. We found that (Cu,Zn)3Cl4(OH)2·2H2O experiences structural changes well above its magnetic transition. Atacamite Cu2(OH)3Cl synthesized under a 0.19 T field experiences a 0.15 K (~3%) decrease in its N\'eel transition temperature and a significant strengthening of its antiferromagnetic interactions, suggesting that magnetosynthesis can influence the ground state of moderately frustrated materials.
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