| Literature DB >> 30511747 |
Francesco Chiabrera1, Iñigo Garbayo1, Lluis López-Conesa2,3,4, Gemma Martín2,3, Alicia Ruiz-Caridad2,3, Michael Walls5, Luisa Ruiz-González6, Apostolos Kordatos7, Marc Núñez1, Alex Morata1, Sonia Estradé2,3, Alexander Chroneos7,8, Francesca Peiró2,3, Albert Tarancón1,9.
Abstract
Interface-dominated materials such as nanocrystalline thin films have emerged as an enthralling class of materials able to engineer functional properties of transition metal oxides widely used in energy and information technologies. In particular, it has been proven that strain-induced defects in grain boundaries of manganites deeply impact their functional properties by boosting their oxygen mass transport while abating their electronic and magnetic order. In this work, the origin of these dramatic changes is correlated for the first time with strong modifications of the anionic and cationic composition in the vicinity of strained grain boundary regions. We are also able to alter the grain boundary composition by tuning the overall cationic content in the films, which represents a new and powerful tool, beyond the classical space charge layer effect, for engineering electronic and mass transport properties of metal oxide thin films useful for a collection of relevant solid-state devices.Entities:
Keywords: grain boundaries; interface-dominated materials; local nonstoichiometry; manganites; nanoionics
Year: 2018 PMID: 30511747 DOI: 10.1002/adma.201805360
Source DB: PubMed Journal: Adv Mater ISSN: 0935-9648 Impact factor: 30.849