Abstract
Polarons in dielectric crystals play a crucial role for applications in integrated electronics and optoelectronics. In this work, we use density-functional theory and Green's function methods to explore the microscopic structure and spectroscopic signatures of electron polarons in lithium niobate (LiNbO3). Total-energy calculations and the comparison of calculated electron paramagnetic resonance data with available measurements reveal the formation of bound polarons at Nb_Li antisite defects with a quasi-Jahn-Teller distorted, tilted configuration. The defect-formation energies further indicate that (bi)polarons may form not only at Nb_Li antisites but also at structures where the antisite Nb atom moves into a neighboring empty oxygen octahedron. Based on these structure models, and on the calculated charge-transition levels and potential-energy barriers, we propose two mechanisms for the optical and thermal splitting of bipolarons, which provide a natural explanation for the reported two-path recombination of bipolarons. Optical-response calculations based on the Bethe-Salpeter equation, in combination with available experimental data and new measurements of the optical absorption spectrum, further corroborate the geometries proposed here for free and defect-bound (bi)polarons.
Highlights
Lithium niobate (LiNbO3, LN) is a dielectric material with many technical applications that exploit its large acoustooptical, piezoelectric, electro-optical, and nonlinear optical coefficients
While formation energies for the NbLi antisite defect in LN were already reported [47,56], the NbV-VLi defect pair was discussed in Ref. [19,30], but its thermodynamic properties, such as the charge-transition levels, have not been explored in detail
We examined the following models: free polarons at regular Nb∗Nb atoms and boundpolarons at two Nb-related point defects, the isolated NbLi antisite, and the NbV-VLi defect pair
Summary
Lithium niobate (LiNbO3, LN) is a dielectric material with many technical applications that exploit its large acoustooptical, piezoelectric, electro-optical, and nonlinear optical coefficients. It is widely used in optical sensors [1], advanced gas sensors [2], waveguides [3], optical modulators [4], and integrated electronics and optoelectronics [5]. The defects resulting from the Li deficiency strongly influence the optical properties of the material [7,8,9]. This study aims at a microscopic understanding of electron polarons and their spectroscopic properties
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