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Autori principali: Martínez, A. Blàzquez, Glinšek, S., Granzow, T., Audinot, J. -N., Fertey, P., Kreisel, J., Guennou, M., Toulouse, C.
Natura: Preprint
Pubblicazione: 2024
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Accesso online:https://arxiv.org/abs/2409.13505
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author Martínez, A. Blàzquez
Glinšek, S.
Granzow, T.
Audinot, J. -N.
Fertey, P.
Kreisel, J.
Guennou, M.
Toulouse, C.
author_facet Martínez, A. Blàzquez
Glinšek, S.
Granzow, T.
Audinot, J. -N.
Fertey, P.
Kreisel, J.
Guennou, M.
Toulouse, C.
contents Strain engineering is a powerful tool routinely used to control and enhance properties such as ferroelectricity, magnetic ordering, or metal-insulator transitions. Epitaxial strain in thin films allows manipulation of in-plane lattice parameters, achieving strain values generally up to 4%, and above in some specific cases. In polycrystalline films, which are more suitable for functional applications due to their lower fabrication costs, strains above 1% often cause cracking. This poses challenges for functional property tuning by strain engineering. Helium implantation has been shown to induce negative pressure through interstitial implantation, which increases the unit cell volume and allows for continuous strain tuning with the implanted dose in epitaxial monocrystalline films. However, there have been no studies on the transferability of helium implantation as a strain-engineering technique to polycrystalline films. Here, we demonstrate the technique's applicability for strain engineering beyond epitaxial monocrystalline samples. Helium implantation can trigger an unprecedented lattice parameter expansion of up to 3.2% in polycrystalline BiFeO3 films without causing structural cracks. The film maintains stable ferroelectric properties with doses up to 1E15 He/cm2. This finding underscores the potential of helium implantation in strain engineering polycrystalline materials, enabling cost-effective and versatile applications.
format Preprint
id arxiv_https___arxiv_org_abs_2409_13505
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Giant Strain Tunability in Polycrystalline Ceramic Films via Helium Implantation
Martínez, A. Blàzquez
Glinšek, S.
Granzow, T.
Audinot, J. -N.
Fertey, P.
Kreisel, J.
Guennou, M.
Toulouse, C.
Materials Science
Strain engineering is a powerful tool routinely used to control and enhance properties such as ferroelectricity, magnetic ordering, or metal-insulator transitions. Epitaxial strain in thin films allows manipulation of in-plane lattice parameters, achieving strain values generally up to 4%, and above in some specific cases. In polycrystalline films, which are more suitable for functional applications due to their lower fabrication costs, strains above 1% often cause cracking. This poses challenges for functional property tuning by strain engineering. Helium implantation has been shown to induce negative pressure through interstitial implantation, which increases the unit cell volume and allows for continuous strain tuning with the implanted dose in epitaxial monocrystalline films. However, there have been no studies on the transferability of helium implantation as a strain-engineering technique to polycrystalline films. Here, we demonstrate the technique's applicability for strain engineering beyond epitaxial monocrystalline samples. Helium implantation can trigger an unprecedented lattice parameter expansion of up to 3.2% in polycrystalline BiFeO3 films without causing structural cracks. The film maintains stable ferroelectric properties with doses up to 1E15 He/cm2. This finding underscores the potential of helium implantation in strain engineering polycrystalline materials, enabling cost-effective and versatile applications.
title Giant Strain Tunability in Polycrystalline Ceramic Films via Helium Implantation
topic Materials Science
url https://arxiv.org/abs/2409.13505