Manipulation of the Ferromagnetism in LaCoO3 Thin Films Through Cation‐Stoichiometric Engineering

Huang, Tongtong; Lyu, Yingjie; Huyan, Huaixun; Ni, Jinyang; Saremi, Sahar; Wang, Yujia; Yan, Xingxu; Yi, Di; He, Qing; Martin, Lane W.; Xiang, Hongjun; Pan, Xiaoqing; Yu, Pu

doi:10.1002/aelm.202201245

Manipulation of the Ferromagnetism in LaCoO3 Thin Films Through Cation‐Stoichiometric Engineering

Huang, Tongtong; Lyu, Yingjie; Huyan, Huaixun; Ni, Jinyang; Saremi, Sahar; Wang, Yujia; Yan, Xingxu; Yi, Di; He, Qing; Martin, Lane W.; Xiang, Hongjun; Pan, Xiaoqing; Yu, Pu

Authors

Tongtong Huang

Yingjie Lyu

Huaixun Huyan

Jinyang Ni

Sahar Saremi

Yujia Wang

Xingxu Yan

Di Yi

Dr Helen He qing.he@durham.ac.uk
Assistant Professor

Lane W. Martin

Hongjun Xiang

Xiaoqing Pan

Pu Yu

Abstract

Spin-state transitions are an important research topic in complex oxides with the diverse magnetic states involved. In particular, the low-spin to high-spin transition in LaCoO3 thin films has drawn a wide range of attention due to the emergent ferromagnetic state. Although various mechanisms (e.g., structural distortion, oxygen-vacancy formation, spin-state ordering) have been proposed, an understanding of what really underlies the emergent ferromagnetism remains elusive. Here, the ferromagnetism in LaCoO3 thin films is systematically modulated by varying the oxygen pressure during thin-film growth. Although the samples show dramatic different magnetization, their cobalt valence state and perovskite crystalline structure remain almost unchanged, ruling out the scenarios of both oxygen-vacancy and spin-ordering. This work provides compelling evidence that the tetragonal distortion due to the tensile strain significantly modifies the orbital occupancy, leading to a low-spin to high-spin transition with emergent ferromagnetism, while samples grown at reduced pressure demonstrate a pronounced lattice expansion due to cation-off-stoichiometry, which suppresses the tetragonal distortion and the consequent magnetization. This result not only provides important insight for the understanding of exotic ferromagnetism in LaCoO3 thin films, but also identifies a promising strategy to design electronic states in complex oxides through cation-stoichiometry engineering.

Citation

Huang, T., Lyu, Y., Huyan, H., Ni, J., Saremi, S., Wang, Y., …Yu, P. (2023). Manipulation of the Ferromagnetism in LaCoO3 Thin Films Through Cation‐Stoichiometric Engineering. Advanced Electronic Materials, 9(5), https://doi.org/10.1002/aelm.202201245

Journal Article Type	Article
Acceptance Date	Feb 10, 2023
Online Publication Date	Mar 9, 2023
Publication Date	2023-05
Deposit Date	Sep 18, 2023
Publicly Available Date	Sep 18, 2023
Journal	Advanced Electronic Materials
Electronic ISSN	2199-160X
Publisher	Wiley
Peer Reviewed	Peer Reviewed
Volume	9
Issue	5
DOI	https://doi.org/10.1002/aelm.202201245
Keywords	Electronic, Optical and Magnetic Materials
Public URL	https://durham-repository.worktribe.com/output/1740958

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