Beyond Epitaxy: Ion Implantation as a Tool for Orbital Engineering

Andreas Herklotz; Jonathan R. Petrie; Thomas Z. Ward

doi:10.1021/acsaelm.5c00815

Beyond Epitaxy: Ion Implantation as a Tool for Orbital Engineering

Andreas Herklotz
, Jonathan R. Petrie
, Thomas Z. Ward

Functional Hybrid Nanomaterials

Research output: Contribution to journal › Article › peer-review

Abstract

Manipulating electronic orbital states in quantum materials provides a powerful means of controlling their physical properties and technological functionality. Here, we demonstrate that orbital populations in strongly correlated oxide thin films can be continuously and reversibly tuned through postsynthesis He ion implantation. Using LaNiO₃as a model system, we show that the orbital preference can be systematically adjusted from favoring in-plane d_x²–y²occupation toward out-of-plane d_z²states through precise control of ion fluence. Unlike conventional heteroepitaxial approaches that lock in orbital configurations during growth, this strain-doping technique enables continuous orbital tuning and the selective modification of specific film regions after device fabrication. We demonstrate the practical impact of this control by achieving a 7-fold enhancement in oxygen reduction reaction catalysis. This work establishes ion implantation as a powerful approach for orbital engineering that complements existing synthesis-based strategies while offering unique advantages for both basic research and device development.

Original language	English
Pages (from-to)	7580-7584
Number of pages	5
Journal	ACS Applied Electronic Materials
Volume	7
Issue number	16
DOIs	https://doi.org/10.1021/acsaelm.5c00815
State	Published - Aug 26 2025

Funding

This material was based on work supported by the U.S. DOE, Office of Science, Basic Energy Sciences, Materials Science and Engineering Division at Oak Ridge National Laboratory (synthesis and characterization). Analysis and conceptualization was conducted at the Center for Nanophase Materials Sciences (CNMS), which is a U.S. Department of Energy, Office of Science User Facility at Oak Ridge National Laboratory. A.H. was funded by the German Research Foundation (DFG, grant no. HE8737/1-1).

Keywords

Nickelates
Orbital Polarization
Oxygen Reduction Reaction
Perovskites
Strain Engineering

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10.1021/acsaelm.5c00815

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title = "Beyond Epitaxy: Ion Implantation as a Tool for Orbital Engineering",

abstract = "Manipulating electronic orbital states in quantum materials provides a powerful means of controlling their physical properties and technological functionality. Here, we demonstrate that orbital populations in strongly correlated oxide thin films can be continuously and reversibly tuned through postsynthesis He ion implantation. Using LaNiO3as a model system, we show that the orbital preference can be systematically adjusted from favoring in-plane dx2–y2occupation toward out-of-plane dz2states through precise control of ion fluence. Unlike conventional heteroepitaxial approaches that lock in orbital configurations during growth, this strain-doping technique enables continuous orbital tuning and the selective modification of specific film regions after device fabrication. We demonstrate the practical impact of this control by achieving a 7-fold enhancement in oxygen reduction reaction catalysis. This work establishes ion implantation as a powerful approach for orbital engineering that complements existing synthesis-based strategies while offering unique advantages for both basic research and device development.",

keywords = "Nickelates, Orbital Polarization, Oxygen Reduction Reaction, Perovskites, Strain Engineering",

author = "Andreas Herklotz and Petrie, \{Jonathan R.\} and Ward, \{Thomas Z.\}",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors. Published by American Chemical Society",

year = "2025",

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doi = "10.1021/acsaelm.5c00815",

language = "English",

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T2 - Ion Implantation as a Tool for Orbital Engineering

AU - Herklotz, Andreas

AU - Petrie, Jonathan R.

AU - Ward, Thomas Z.

PY - 2025/8/26

Y1 - 2025/8/26

N2 - Manipulating electronic orbital states in quantum materials provides a powerful means of controlling their physical properties and technological functionality. Here, we demonstrate that orbital populations in strongly correlated oxide thin films can be continuously and reversibly tuned through postsynthesis He ion implantation. Using LaNiO3as a model system, we show that the orbital preference can be systematically adjusted from favoring in-plane dx2–y2occupation toward out-of-plane dz2states through precise control of ion fluence. Unlike conventional heteroepitaxial approaches that lock in orbital configurations during growth, this strain-doping technique enables continuous orbital tuning and the selective modification of specific film regions after device fabrication. We demonstrate the practical impact of this control by achieving a 7-fold enhancement in oxygen reduction reaction catalysis. This work establishes ion implantation as a powerful approach for orbital engineering that complements existing synthesis-based strategies while offering unique advantages for both basic research and device development.

AB - Manipulating electronic orbital states in quantum materials provides a powerful means of controlling their physical properties and technological functionality. Here, we demonstrate that orbital populations in strongly correlated oxide thin films can be continuously and reversibly tuned through postsynthesis He ion implantation. Using LaNiO3as a model system, we show that the orbital preference can be systematically adjusted from favoring in-plane dx2–y2occupation toward out-of-plane dz2states through precise control of ion fluence. Unlike conventional heteroepitaxial approaches that lock in orbital configurations during growth, this strain-doping technique enables continuous orbital tuning and the selective modification of specific film regions after device fabrication. We demonstrate the practical impact of this control by achieving a 7-fold enhancement in oxygen reduction reaction catalysis. This work establishes ion implantation as a powerful approach for orbital engineering that complements existing synthesis-based strategies while offering unique advantages for both basic research and device development.

KW - Nickelates

KW - Orbital Polarization

KW - Oxygen Reduction Reaction

KW - Perovskites

KW - Strain Engineering

UR - https://www.scopus.com/pages/publications/105014537974

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DO - 10.1021/acsaelm.5c00815

M3 - Article

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EP - 7584

JO - ACS Applied Electronic Materials

JF - ACS Applied Electronic Materials

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ER -

Beyond Epitaxy: Ion Implantation as a Tool for Orbital Engineering

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