Improving 2D-ness to enhance thermopower in oxide superlattices

TL;DR

This paper demonstrates that enhancing two-dimensional confinement in EuTiO3-based superlattices significantly boosts thermopower, offering new pathways for designing high-performance oxide thermoelectrics.

Contribution

It introduces EuTiO3 as an alternative platform and shows how 2D confinement and Eu 4f-states improve thermopower in oxide superlattices.

Findings

Achieved a quasi-2D thermopower of -950 μV/K.

Observed a S2D/S3D ratio of approximately 20.

Identified the role of Eu 4f-states in enhancing 2D confinement.

Abstract

The transport dynamics of itinerant charge carriers and their interactions with the environment. For two-dimensional oxide thermoelectrics, predominantly represented by doped SrTiO3-based superlattices, reduced spatial dimensions and increased effective mass are known to enhance thermopower (S). However, because of their large effective Bohr radius resulting from their high dielectric constant, SrTiO3-based systems have limitations in exhibiting the 2D characteristic. Here, we focus on EuTiO3 as an alternative perovskite platform in which fractional LaxEu1-xTiO3/EuTiO3 artificial superlattices demonstrate the improvement in 2D nature for the dimensionality-induced improvement of S. We observed a quasi-2D thermopower S2D of -950 uV K-1 and S2D/S3D of ~20 resulting from the improved 2D confinement. Thermopower measurements, combined with hybrid density functional theory calculations, show the enhanced S originates from the confinement of Ti 3dxy-states within the LaxEu1-xTiO3 layers and the associated increase in the 2D density of states. In detail, a smaller effective Bohr radius and modified electronic band structures, in conjunction with the presence of the Eu 4f-states in EuTiO3 which modified the local electronic potential and strengthened the spatial confinement of Ti 3d-states. This approach to improving the dimensional confinement establishes a small effective Bohr radius and Eu 4f-state assisted 2D confinement provides valuable insights into the design of high-performance applications in artificial oxide superlattices.