Origin of the Magnetic Exciton in the van der Waals Antiferromagnet NiPS_{3}

An ultrasharp photoluminescence line intimately related to antiferromagnetic order has been found in NiPS_{3}, a correlated van der Waals material, opening prospects for magneto-optical coupling schemes and spintronic applications. Here we unambiguously clarify the singlet origin of this excitation, confirming its roots in the spin structure. Based on a comprehensive investigation of the electronic structure using angle-resolved photoemission and q-dependent electron energy loss spectroscopy as experimental tools we develop, in a first step, an adequate theoretical understanding using density functional theory (DFT). In a second step the DFT is used as input for a dedicated multiplet theory by which we achieve excellent agreement with available multiplet spectroscopy. Our Letter connects the understanding of the electronic structure and of optical processes in NiPS_{3} and related materials as a prerequisite for further progress of the field.

The crystal growth and properties of novel magnetic double molybdate RbFe5(MoO4)7 with mixed Fe3+/Fe2+ states and 1D negative thermal expansion

Single crystals of new composition RbFe₅(MoO₄)₇ were successfully grown by the flux method, and their crystal structure was determined using the X-ray single-crystal diffraction technique.

Composition-dependent charge transfer and phase separation in the V1-xRexO2 solid solution

The substitution of vanadium in vanadium dioxide VO₂ influences the critical temperatures of structural and metal-to-insulator transitions in different ways depending on the valence of the dopant. Rhenium adopts valence states between +4 and +7 in an octahedral oxygen surrounding and is particularly interesting in this context. Structural investigation of V_1-xRe_xO₂ solid solutions (0.01 ≤ x ≤ 0.30) between 80 and 1200 K using synchrotron X-ray powder diffraction revealed only two polymorphs that resemble VO₂: the low-temperature monoclinic MoO₂-type form (space group P2₁/c), and the tetragonal rutile-like form (space group P4₂/mnm). However, for compositions with 0.03 < x ≤ 0.15 a phase separation in the solid solution was observed below 1000 K upon cooling down from 1200 K, giving rise to two isostructural phases with slightly different lattice parameters. This is reflected in the appearance of two metal-to-insulator transition temperatures detected by magnetization and specific heat measurements. Comprehensive X-ray photoelectron spectroscopy studies showed that an increased amount of Re leads to a change in the Re valence state from solely Re⁶⁺ at a low doping level (≤3 at% Re) via mixed-valence states Re⁴⁺/Re⁶⁺ for at least 0.03 < x ≤ 0.10, up to nearly pure Re⁴⁺ in V_0.70Re_0.30O₂. Thus, compositions V_1-xRe_xO₂ with only one valence state of Re in the material (Re⁶⁺ or Re⁴⁺) can be obtained as a single phase, while intermediate compositions are subjected to a phase separation, presumably due to different valence states of Re.

Correction: Composition-dependent charge transfer and phase separation in the V1−xRexO2 solid solution

Correction for ‘Composition-dependent charge transfer and phase separation in the V_1−xRe_xO₂ solid solution’ by D. Mikhailova, et al., Dalton Trans., 2017, 46, 1606–1617.