Anisotropic optical response of the mixed-valent Mott-Hubbard insulator NaCu2O2

TL;DR

This study investigates the anisotropic optical properties of NaCu2O2 using spectroscopic ellipsometry and density-functional calculations, revealing detailed electronic transitions and their temperature dependence related to its mixed-valent Mott-Hubbard insulating state.

Contribution

It provides the first comprehensive spectroscopic analysis of NaCu2O2's anisotropic dielectric response and links optical features to specific electronic band transitions and Coulomb interactions.

Findings

Strong in-plane anisotropy of interband excitations observed.

Identification of specific electronic transitions involving Cu1+ and Cu2+ orbitals.

Temperature-dependent features linked to spin correlations and Coulomb interactions.

Abstract

We report the results of a comprehensive spectroscopic ellipsometry study of NaCu2O2, a compound composed of chains of edge-sharing Cu2+O4 plaquettes and planes of Cu1+ ions in a O-Cu1+-O dumbbell configuration, in the spectral range 0.75-6.5 eV at temperatures 7 -300 K. The spectra of the dielectric function for light polarized parallel to the Cu1+ planes reveal a strong in-plane anisotropy of the interband excitations. Strong and sharp absorption bands peaked at 3.45 eV (3.7 eV) dominate the spectra for polarization along (perpendicular) to the Cu2+O2 chains. They are superimposed on flat and featureless plateaux above the absorption edges at 2.25 eV (2.5 eV). Based on density-functional calculations, the anomalous absorption peaks can be assigned to transitions between bands formed by Cu1+ 3dxz(dyz) and Cu2+ 3dxy orbitals, strongly hybridized with O pstates. The major contribution to the background response comes from transitions between Cu1+ 3dz2 and 4px(py) bands. This assignment accounts for the measured in-plane anisotropy. The dielectric response along the Cu2+O2 chains develops a weak two-peak structure centered at 2.1 and 2.65 eV upon cooling below 100 K, along with the appearance of spin correlations along the Cu2+O2 chains. These features bear a striking resemblance to those observed in the single-valent Cu2+O2 chain compound LiCuVO4, which were identified as an exciton doublet associated with transitions to the upper Hubbard band that emerges as a consequence of the long-range Coulomb interaction between electrons on neighboring Cu2+ sites along the chains. An analysis of the spectral weights of these features yields the parameters characterizing the on-site and long-range Coulomb interactions.