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  Liu, C.-Y.; Feng, P.; Ruotsalainen, K.; Bauer, K.; Decker, R.; Kusch, M.; Siewierska, K.; Pietzsch, A.; Haase, M.; Lu, Y.; de Groot, F.; Föhlisch, A.: Role of La 5p in bulk and quantum-confined solids probed by the La 5p⁵4f^{1 3}D₁ excitonic final state of resonant inelastic x-ray scattering. The Journal of Physical Chemistry C 127 (2023), p. 11111-11118

10.1021/acs.jpcc.3c02011
Open Access Version

Abstract:
The varied electronic localization of rare earth elements is essential to functional materials and a key to tailoring their properties. We establish with unprecedented spectral resolution the excitonic nature of the lanthanum 5p54f1 3D1 and 3D2 final states of resonant inelastic X-ray scattering (RIXS) at the La N4,5 edges. We extract the intrinsic lifetime, energy distance, and relative intensity ratio from single crystal LaAlO3 and construct an empirical model. With help of the model, we precisely determine the RIXS 3D1 final state position and identify La 5p as a descriptor of covalency with the host material. For metallic lanthanum, La3+ ions in mixed-covalent-ionic simple oxides and phosphates, and ionic salts alike, we find a sizable chemical shift, indicating band-like and free-ion-like La. The different electronic relaxation of the La 5p5 hole and the La 4f1 electron is discussed with local and nonlocal screening contributions. In addition, the energetics of the excitonic La 5p54f1 Coulomb attraction is quantified in its variation from lanthanum metal to mixed-covalent-ionic La2O3 and the ionic LaF3 salt. The power of the approach and analysis is applied to map the influence of geometric quantum confinement to La 5p sharing within quantum dots and quantum wires in comparison to bulk-like microrods of monoclinic LaPO4.