Zeeman and Davydov splitting of Frenkel excitons in the antiferromagnet CuB2O4

Abstract

The optical spectra of antiferromagnetic copper metaborate CuB2O4 are characterized by an exceptionally rich structure of narrow absorption lines due to electronic transitions within the magnetic Cu2+ ions, but their unambiguous identification and behavior in magnetic field remain far from being fully understood. We studied the polarized magneto-absorption spectra of this tetragonal antiferromagnet with a high spectral resolution in the range of 1.4055-1.4065 eV in magnetic fields up to 9.5 T and temperatures from 1.6 up to TN = 20 K. We observed a set of eight absorption lines at T=1.6 K in magnetic fields exceeding 1.4 T which we identified as arising from Frenkel excitons related to the ground and the first excited state of Cu2+ ions. The number of these excitons is defined by the presence of the four Cu2+ ions with the doubly-degenerate spin state S = 1/2 at the 4b positions in the crystallographic unit cell. The energies of these excitons are determined the exchange interaction of 0.5 meV of Cu2+ ions in the excited state with surrounding ions and by the Davydov splitting of 0.12 meV. In large magnetic field the observed Zeeman splitting is controlled by the anisotropic g-factors of both the ground and excited states. We developed a theoretical model of Frenkel excitons in magnetic field that accounts for specific features of the spin structure and exchange interactions in CuB2O4. The model was used for fitting the experimental data and evaluation of Frenkel exciton parameters, such as the Davydov splitting, the molecular exchange energy, and the g-factors of the ground and excited states of the Cu2+ ions.