Synchrotron Mössbauer spectroscopic study of ferropericlase at high pressures and temperatures

Abstract

The electronic spin state of Fe²⁺ in ferropericlase, (Mg_0.75Fe_0.25)O, transitions from a high-spin (spin unpaired) to low-spin (spin paired) state within the Earth’s mid-lower mantle region. To better understand the local electronic environment of high-spin Fe²⁺ ions in ferropericlase near the transition, we obtained synchrotron Mössbauer spectra (SMS) of (Mg_0.75,Fe_0.25)O in externally heated and laser-heated diamond anvil cells at relevant high pressures and temperatures. Results show that the quadrupole splitting (QS) of the dominant high-spin Fe²⁺ site decreases with increasing temperature at static high pressure. The QS values at constant pressure are fitted to a temperature-dependent Boltzmann distribution model, which permits estimation of the crystal-field splitting energy (Δ₃) between the d_xy and d_xz or d_zy orbitals of the t_2g states in a distorted octahedral Fe²⁺ site. The derived Δ₃ increases from approximately 36 meV at 1 GPa to 95 meV at 40 GPa, revealing that both high pressure and high temperature have significant effects on the 3d electronic shells of Fe²⁺ in ferropericlase. The SMS spectra collected from the laser-heated diamond cells within the time window of 146 ns also indicate that QS significantly decreases at very high temperatures. A larger splitting of the energy levels at high temperatures and pressures should broaden the spin crossover in ferropericlase because the degeneracy of energy levels is partially lifted. Our results provide information on the hyperfine parameters and crystal-field splitting energy of high-spin Fe²⁺ in ferropericlase at high pressures and temperatures, relevant to the electronic structure of iron in oxides in the deep lower mantle.