Epitaxial Stabilization and Oxygen Vacancy Control of EuNiO3 Thin Films: Article No. 085301

Christopher Muzzillo; Keon Sahebkar; Michelle Smeaton; Olivia Schneble; Sang-Jun Lee; Hirohito Ogasawara; Rebecca Smaha; William Callahan; Ryan Need; M. Brooks Tellekamp

doi:10.1063/5.0271577

Epitaxial Stabilization and Oxygen Vacancy Control of EuNiO3 Thin Films: Article No. 085301

Christopher Muzzillo, Keon Sahebkar, Michelle Smeaton, Olivia Schneble, Sang-Jun Lee, Hirohito Ogasawara, Rebecca Smaha, William Callahan, Ryan Need, M. Brooks Tellekamp

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

Abstract

Rare-earth nickelates exhibit valuable behavior for neuromorphic computing at low temperature: Building blocks for biologically inspired microelectronic neurons like electrically driven insulator-metal transitions (IMTs), negative differential resistance, and self-oscillations have been shown up to 230 K for SmNiO3 and NdNiO3. EuNiO3 raises the IMT far above room temperature (460 K) but high-quality thin films are challenging to synthesize. Here, we explore the epitaxial stabilization of EuNiO3 using pulsed laser deposition. X-ray diffraction reciprocal space maps, x-ray absorption spectroscopy, and transmission electron microscopy show that higher growth temperature (800 degrees C) reduces oxygen vacancy concentrations in EuNiO3. Pseudomorphic EuNiO3 is demonstrated on both SrLaAlO4 and NdGaO3 substrates, and LaNiO3 buffer layers are incorporated to facilitate future vertical device fabrication. In contrast to bulk thermodynamic predictions, the greater oxidation and crystallinity at higher temperature we observe indicates that epitaxial substrates can stabilize EuNiO3 at O2 pressures less than 1 atm.

Original language	American English
Number of pages	11
Journal	Journal of Applied Physics
Volume	138
Issue number	8
DOIs	https://doi.org/10.1063/5.0271577
State	Published - 2025

NREL Publication Number

NREL/JA-5K00-93849

Keywords

epitaxy
EuNiO3
neuromorphic
nickelate

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10.1063/5.0271577

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@article{ff0868dc1830483fb65925e0f46ac021,

title = "Epitaxial Stabilization and Oxygen Vacancy Control of EuNiO3 Thin Films: Article No. 085301",

abstract = "Rare-earth nickelates exhibit valuable behavior for neuromorphic computing at low temperature: Building blocks for biologically inspired microelectronic neurons like electrically driven insulator-metal transitions (IMTs), negative differential resistance, and self-oscillations have been shown up to 230 K for SmNiO3 and NdNiO3. EuNiO3 raises the IMT far above room temperature (460 K) but high-quality thin films are challenging to synthesize. Here, we explore the epitaxial stabilization of EuNiO3 using pulsed laser deposition. X-ray diffraction reciprocal space maps, x-ray absorption spectroscopy, and transmission electron microscopy show that higher growth temperature (800 degrees C) reduces oxygen vacancy concentrations in EuNiO3. Pseudomorphic EuNiO3 is demonstrated on both SrLaAlO4 and NdGaO3 substrates, and LaNiO3 buffer layers are incorporated to facilitate future vertical device fabrication. In contrast to bulk thermodynamic predictions, the greater oxidation and crystallinity at higher temperature we observe indicates that epitaxial substrates can stabilize EuNiO3 at O2 pressures less than 1 atm.",

keywords = "epitaxy, EuNiO3, neuromorphic, nickelate",

author = "Christopher Muzzillo and Keon Sahebkar and Michelle Smeaton and Olivia Schneble and Sang-Jun Lee and Hirohito Ogasawara and Rebecca Smaha and William Callahan and Ryan Need and Tellekamp, \{M. Brooks\}",

year = "2025",

doi = "10.1063/5.0271577",

language = "American English",

volume = "138",

journal = "Journal of Applied Physics",

issn = "0021-8979",

publisher = "American Institute of Physics",

number = "8",

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TY - JOUR

T1 - Epitaxial Stabilization and Oxygen Vacancy Control of EuNiO3 Thin Films

T2 - Article No. 085301

AU - Muzzillo, Christopher

AU - Sahebkar, Keon

AU - Smeaton, Michelle

AU - Schneble, Olivia

AU - Lee, Sang-Jun

AU - Ogasawara, Hirohito

AU - Smaha, Rebecca

AU - Callahan, William

AU - Need, Ryan

AU - Tellekamp, M. Brooks

PY - 2025

Y1 - 2025

N2 - Rare-earth nickelates exhibit valuable behavior for neuromorphic computing at low temperature: Building blocks for biologically inspired microelectronic neurons like electrically driven insulator-metal transitions (IMTs), negative differential resistance, and self-oscillations have been shown up to 230 K for SmNiO3 and NdNiO3. EuNiO3 raises the IMT far above room temperature (460 K) but high-quality thin films are challenging to synthesize. Here, we explore the epitaxial stabilization of EuNiO3 using pulsed laser deposition. X-ray diffraction reciprocal space maps, x-ray absorption spectroscopy, and transmission electron microscopy show that higher growth temperature (800 degrees C) reduces oxygen vacancy concentrations in EuNiO3. Pseudomorphic EuNiO3 is demonstrated on both SrLaAlO4 and NdGaO3 substrates, and LaNiO3 buffer layers are incorporated to facilitate future vertical device fabrication. In contrast to bulk thermodynamic predictions, the greater oxidation and crystallinity at higher temperature we observe indicates that epitaxial substrates can stabilize EuNiO3 at O2 pressures less than 1 atm.

AB - Rare-earth nickelates exhibit valuable behavior for neuromorphic computing at low temperature: Building blocks for biologically inspired microelectronic neurons like electrically driven insulator-metal transitions (IMTs), negative differential resistance, and self-oscillations have been shown up to 230 K for SmNiO3 and NdNiO3. EuNiO3 raises the IMT far above room temperature (460 K) but high-quality thin films are challenging to synthesize. Here, we explore the epitaxial stabilization of EuNiO3 using pulsed laser deposition. X-ray diffraction reciprocal space maps, x-ray absorption spectroscopy, and transmission electron microscopy show that higher growth temperature (800 degrees C) reduces oxygen vacancy concentrations in EuNiO3. Pseudomorphic EuNiO3 is demonstrated on both SrLaAlO4 and NdGaO3 substrates, and LaNiO3 buffer layers are incorporated to facilitate future vertical device fabrication. In contrast to bulk thermodynamic predictions, the greater oxidation and crystallinity at higher temperature we observe indicates that epitaxial substrates can stabilize EuNiO3 at O2 pressures less than 1 atm.

KW - epitaxy

KW - EuNiO3

KW - neuromorphic

KW - nickelate

U2 - 10.1063/5.0271577

DO - 10.1063/5.0271577

M3 - Article

SN - 0021-8979

VL - 138

JO - Journal of Applied Physics

JF - Journal of Applied Physics

IS - 8

ER -

Epitaxial Stabilization and Oxygen Vacancy Control of EuNiO3 Thin Films: Article No. 085301

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NREL Publication Number

Keywords

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