Precise determination of low energy electronuclear Hamiltonian for LiY1-xHoxF4

Abstract

We use complementary optical spectroscopy methods to directly measure the lowest crystal-field energies of the rare-earth quantum magnet LiY1-xHoxF4, including their hyperfine splittings, with more than 10 times higher resolution than previous work. We are able to observe energy level splittings due to the 6Li and 7Li isotopes, as well as non-equidistantly spaced hyperfine transitions originating from dipolar and quadrupolar hyperfine interactions. We provide refined crystal field parameters and extract the dipolar and quadrupolar hyperfine constants AJ=0.027030.00003 cm-1 and B= 0.04 0.01 cm-1, respectively. Thereupon we determine all crystal-field energy levels and magnetic moments of the 5I8 ground state manifold, including the (non-linear) hyperfine corrections. The latter match the measurement-based estimates. The scale of the non-linear hyperfine corrections sets an upper bound for the inhomogeneous line widths that would still allow for unique addressing of a selected hyperfine transition. e.g. for quantum information applications. Additionally, we establish the far-infrared, low-temperature refractive index of LiY1-xHoxF4.