Low-energy Mott-Hubbard excitations in LaMnO_3 probed by optical ellipsometry

TL;DR

This study uses optical ellipsometry to investigate the anisotropic electronic excitations in LaMnO_3, revealing temperature-dependent spectral weight transfer linked to magnetic ordering and providing insights into the underlying electronic interactions.

Contribution

It offers a detailed analysis of low-energy Mott-Hubbard excitations in LaMnO_3, combining experimental ellipsometry data with a theoretical spin-orbital superexchange model to elucidate electronic interactions.

Findings

Identification of the 2 eV transition as an intersite d-d transition.

Observation of spectral weight transfer with magnetic ordering.

Estimation of Coulomb, Hund, and Jahn-Teller energies in LaMnO_3.

Abstract

We present a comprehensive ellipsometric study of an untwinned, nearly stoichiometric LaMnO_3 crystal in the spectral range 1.2-6.0 eV at temperatures 20 K < T < 300 K. The complex dielectric response along the b and c axes of the Pbnm orthorhombic unit cell, \epsilon^b(\nu) and \epsilon^c(\nu), is highly anisotropic over the spectral range covered in the experiment. The difference between \epsilon^b(\nu) and \epsilon^c(\nu) increases with decreasing temperature, and the gradual evolution observed in the paramagnetic state is strongly enhanced by the onset of A-type antiferromagnetic long-range order at T_N = 139.6 K. In addition to the temperature changes in the lowest-energy gap excitation at 2 eV, there are opposite changes observed at higher energy at 4 - 5 eV, appearing on a broad-band background due to the strongly dipole-allowed O 2p -- Mn 3d transition around the charge-transfer energy 4.7 eV. Based on the observation of a pronounced spectral-weight transfer between low- and high-energy features upon magnetic ordering, they are assigned to high-spin and low-spin intersite d^4d^4 - d^3d^5 transitions by Mn electrons. The anisotropy of the lowest-energy optical band and the spectral weight shifts induced by antiferromagnetic spin correlations are quantitatively described by an effective spin-orbital superexchange model. An analysis of the multiplet structure of the intersite transitions by Mn e_g electrons allowed us to estimate the effective intra-atomic Coulomb interaction, the Hund exchange coupling, and the Jahn-Teller splitting energy between e_g orbitals in LaMnO_3. This study identifies the lowest-energy optical transition at 2 eV as an intersite d-d transition, whose energy is substantially reduced compared to that obtained from the bare intra-atomic Coulomb interaction.