Interfacial charge-transfer in 3d/5d complex oxide heterostructures
Abstract
Interfacial charge transfer (ICT) provides a powerful route to engineer electronic phases in correlated oxide heterostructures, yet predictive design principles remain elusive. Here, we systematically investigate superlattices composed of the 5d spin-orbit coupled semimetal SrIrO3 and a series of correlated 3d perovskites (LaMnO3, LaFeO3, LaCoO3, and NdNiO3), thereby establishing a quantitative framework for ICT across 3d/5d interfaces. Combining element-specific x-ray absorption spectroscopy with spatially resolved electron energy loss spectroscopy, a homogeneous electron transfer from the 5d to the 3d layers is directly quantified, reaching up to 0.35 e per unit cell in the cobaltate superlattice. We show that the magnitude of ICT scales linearly with the difference in electronegativity between the transition-metal oxide layers, identifying electronegativity-driven band alignment as the dominant mechanism for ICT. Beyond interfacial doping, we find that strong 3d-5d hybridization induces a complete low-spin to high-spin conversion in the cobaltate layers, demonstrating interface-controlled spin-state engineering without chemical substitution. These results establish electronegativity mismatch as a predictive design parameter for correlated oxide interfaces and provide a materials platform for tailoring band filling, orbital hierarchy, and spin configurations in quantum oxide heterostructures, paving the way towards advanced oxide electronics and next-generation information technologies.
Keywords
Cite
@article{arxiv.2603.25514,
title = {Interfacial charge-transfer in 3d/5d complex oxide heterostructures},
author = {Arun Kumar Jaiswal and Di Wang and Ji Soo Lim and Shruti Roy and Fabrice Wilhelm and Vanessa Wollersen and Andrei Rogalev and Matthieu Le Tacon and Dirk Fuchs},
journal= {arXiv preprint arXiv:2603.25514},
year = {2026}
}
Comments
16 pages, 5 figures, 1 table