La-doped BaSnO₃ (BLSO, Pm-3m, a=4.115 Å, E_g~3.1 eV) single crystal exhibit very high mobility of 320 cm² V⁻¹ s⁻¹.^[1] Therefore, BLSO has attracted increasing attention as a novel transparent oxide semiconductor for advanced transparent electronic devices. Recently, many researchers were trying to realize high mobility BLSO thin films. However, the reported mobilities are still far lower than that of single crystals. The origin of mobility suppression of BLSO was considered boundary scattering at columnar domain boundaries, which are generated due to the lattice mismatch (eg. SrTiO₃ +5.4 %). In order to minimize the lattice mismatch, Lee et al. used BaSnO₃ single crystals as the substrates. However, the resultant mobilities were <100 cm² V⁻¹ s⁻¹, ^[2] suggesting that the main origin is NOT lattice mismatch.
In order to clarify the main origin of the mobility suppression, we measured the electron transport properties of the BLSO (Ba_0.98La_0.02SnO₃) epitaxial films with varied thickness (20−1000 nm), which were grown on (001) SrTiO₃ (Δa=+5.4 %) or (001) MgO (Δa=−2.3 %) by PLD. Figure summarizes (a) the carrier concentration (n), (b) thermopower and (c) Hall mobility (μ_Hall) of the resultant films as a function of the BLSO thickness at room temperature. Regarding the overall tendencies, no clear difference is observed on SrTiO₃ and MgO substrates. The n increases with thickness and approaching to the nominal n (=[2.87×10²⁰ cm⁻³]). The S changes simultaneously with n. The μ_Hall also increases with thickness and reaches the maximum value of ~100 cm² V⁻¹ s⁻¹.
These results clearly indicate that the lattice mismatch is not the main origin of mobility suppression but doped La³⁺ ions were not activated at around the film/substrate interfaces. Thus, we should clarify the origin of La³⁺ inactivation at around the films/substrate interfaces to improve the electron mobility of BLSO films.