ErAl:Al2O3 for Telecom-Band Photonics: Electronic Structure and Optical Properties

Abstract

Er-doped Al2O3 is a promising host for telecom-band integrated photonics. Here we combine ab initio calculations with a symmetry-resolved analysis to elucidate substitutional Er on the Al site (ErAl) in α-Al2O3. First-principles relaxations confirm the structural stability of ErAl. We then use the local trigonal crystal-field symmetry to classify the Er-derived impurity levels by irreducible representations and to derive polarization-resolved electric-dipole selection rules, explicitly identifying the symmetry-allowed f hybridization channels. Kubo--Greenwood absorption spectra computed from Kohn--Sham states quantitatively corroborate these symmetry predictions. Furthermore, we connect the calculated intra-4f line strengths to Judd--Ofelt theory, clarifying the role of 4f5d admixture in enabling optical activity. Notably, we predict a characteristic absorption near 1.47~μm (telecom band), relevant for on-chip amplification and emission. To our knowledge, a symmetry-resolved first-principles treatment of Er:Al2O3 with an explicit Judd--Ofelt interpretation has not been reported, providing a transferable framework for tailoring rare-earth dopants in wide-band-gap oxides for integrated photonics. Our results for the optical spectra are in good agreement with experimental data.