Striped nanoscale phase separation at the metal-insulator transition of heteroepitaxial nickelates

G. Mattoni; P. Zubko; F. Maccherozzi; A. J H Van Der Torren; D. B. Boltje; M. Hadjimichael; N. Manca; S. Catalano; M. Gibert; Y. Liu; J. Aarts; J. M. Triscone; S. S. Dhesi; A. D. Caviglia

doi:10.1038/ncomms13141

Striped nanoscale phase separation at the metal-insulator transition of heteroepitaxial nickelates

G. Mattoni^*, P. Zubko, F. Maccherozzi, A. J H Van Der Torren, D. B. Boltje, M. Hadjimichael, N. Manca, S. Catalano, M. Gibert, Y. Liu, J. Aarts, J. M. Triscone, S. S. Dhesi, A. D. Caviglia

^*Corresponding author for this work

QN/Caviglia Lab

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

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Abstract

Nucleation processes of mixed-phase states are an intrinsic characteristic of first-order phase transitions, typically related to local symmetry breaking. Direct observation of emerging mixed-phase regions in materials showing a first-order metal-insulator transition (MIT) offers unique opportunities to uncover their driving mechanism. Using photoemission electron microscopy, we image the nanoscale formation and growth of insulating domains across the temperature-driven MIT in NdNiO₃ epitaxial thin films. Heteroepitaxy is found to strongly determine the nanoscale nature of the phase transition, inducing preferential formation of striped domains along the terraces of atomically flat stepped surfaces. We show that the distribution of transition temperatures is a local property, set by surface morphology and stable across multiple temperature cycles. Our data provide new insights into the MIT of heteroepitaxial nickelates and point to a rich, nanoscale phenomenology in this strongly correlated material.

Original language	English
Article number	13141
Pages (from-to)	1-7
Number of pages	7
Journal	Nature Communications
Volume	7
DOIs	https://doi.org/10.1038/ncomms13141
Publication status	Published - 2 Nov 2016

Bibliographical note

Kavli Institute of Nanoscience, Delft University of Technology

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Mattoni, G., Zubko, P., Maccherozzi, F., Van Der Torren, A. J. H., Boltje, D. B., Hadjimichael, M., Manca, N., Catalano, S., Gibert, M., Liu, Y., Aarts, J., Triscone, J. M., Dhesi, S. S., & Caviglia, A. D. (2016). Striped nanoscale phase separation at the metal-insulator transition of heteroepitaxial nickelates. Nature Communications, 7, 1-7. Article 13141. https://doi.org/10.1038/ncomms13141

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abstract = "Nucleation processes of mixed-phase states are an intrinsic characteristic of first-order phase transitions, typically related to local symmetry breaking. Direct observation of emerging mixed-phase regions in materials showing a first-order metal-insulator transition (MIT) offers unique opportunities to uncover their driving mechanism. Using photoemission electron microscopy, we image the nanoscale formation and growth of insulating domains across the temperature-driven MIT in NdNiO3 epitaxial thin films. Heteroepitaxy is found to strongly determine the nanoscale nature of the phase transition, inducing preferential formation of striped domains along the terraces of atomically flat stepped surfaces. We show that the distribution of transition temperatures is a local property, set by surface morphology and stable across multiple temperature cycles. Our data provide new insights into the MIT of heteroepitaxial nickelates and point to a rich, nanoscale phenomenology in this strongly correlated material.",

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AU - Mattoni, G.

AU - Zubko, P.

AU - Maccherozzi, F.

AU - Van Der Torren, A. J H

AU - Boltje, D. B.

AU - Hadjimichael, M.

AU - Manca, N.

AU - Catalano, S.

AU - Gibert, M.

AU - Liu, Y.

AU - Aarts, J.

AU - Triscone, J. M.

AU - Dhesi, S. S.

AU - Caviglia, A. D.

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Y1 - 2016/11/2

N2 - Nucleation processes of mixed-phase states are an intrinsic characteristic of first-order phase transitions, typically related to local symmetry breaking. Direct observation of emerging mixed-phase regions in materials showing a first-order metal-insulator transition (MIT) offers unique opportunities to uncover their driving mechanism. Using photoemission electron microscopy, we image the nanoscale formation and growth of insulating domains across the temperature-driven MIT in NdNiO3 epitaxial thin films. Heteroepitaxy is found to strongly determine the nanoscale nature of the phase transition, inducing preferential formation of striped domains along the terraces of atomically flat stepped surfaces. We show that the distribution of transition temperatures is a local property, set by surface morphology and stable across multiple temperature cycles. Our data provide new insights into the MIT of heteroepitaxial nickelates and point to a rich, nanoscale phenomenology in this strongly correlated material.

AB - Nucleation processes of mixed-phase states are an intrinsic characteristic of first-order phase transitions, typically related to local symmetry breaking. Direct observation of emerging mixed-phase regions in materials showing a first-order metal-insulator transition (MIT) offers unique opportunities to uncover their driving mechanism. Using photoemission electron microscopy, we image the nanoscale formation and growth of insulating domains across the temperature-driven MIT in NdNiO3 epitaxial thin films. Heteroepitaxy is found to strongly determine the nanoscale nature of the phase transition, inducing preferential formation of striped domains along the terraces of atomically flat stepped surfaces. We show that the distribution of transition temperatures is a local property, set by surface morphology and stable across multiple temperature cycles. Our data provide new insights into the MIT of heteroepitaxial nickelates and point to a rich, nanoscale phenomenology in this strongly correlated material.

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Striped nanoscale phase separation at the metal-insulator transition of heteroepitaxial nickelates

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