Synthesis of single-crystal La0.67Sr0.33MnO3 freestanding films with different crystal-orientation

Lu, Zengxing; Lu, Shanping; Feng, Jiatai; Zheng, Xuan; Yang, Lihong; Chen, Ge; Jin, Kui-juan; Wang, Zhiming; Li, Run-Wei

doi:10.1063/1.5145029

Cited by 38 publications

(37 citation statements)

References 32 publications

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“…This contrasts with other reports which show larger increases in resistivity (e.g. 80% in LSMO reported by Di Lu et al [32], ~ 700% in LSMO reported by Zengxing Lu et al [46]).…”

Section: Srruo 3 Free-standing Filmscontrasting

confidence: 83%

“…The first step in the process of getting a perfect freestanding film is to grow the target single-crystal oxide thin film with a well-defined orientation. Several studies using pulsed laser deposition (PLD) and molecular-beam epitaxy (MBE) have demonstrated growth of single crystalline films on Sr 3 Al 2 O 6 sacrificial layers [32,39,46,47]. The layer is coherently strained to the STO when it is very thin (around 10 nm).…”

Section: New Methods To Transfer Epitaxial Oxide Thin Filmsmentioning

confidence: 99%

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High Yield Transfer of Clean Large-Area Epitaxial Oxide Thin Films

2021

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In this work, we have developed a new method for manipulating and transferring up to 5 mm × 10 mm epitaxial oxide thin films. The method involves fixing a PET frame onto a PMMA attachment film, enabling transfer of epitaxial films lifted-off by wet chemical etching of a Sr3Al2O6 sacrificial layer. The crystallinity, surface morphology, continuity, and purity of the films are all preserved in the transfer process. We demonstrate the applicability of our method for three different film compositions and structures of thickness ~ 100 nm. Furthermore, we show that by using epitaxial nanocomposite films, lift-off yield is improved by ~ 50% compared to plain epitaxial films and we ascribe this effect to the higher fracture toughness of the composites. This work shows important steps towards large-scale perovskite thin-film-based electronic device applications.

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“…This contrasts with other reports which show larger increases in resistivity (e.g. 80% in LSMO reported by Di Lu et al [32], ~ 700% in LSMO reported by Zengxing Lu et al [46]).…”

Section: Srruo 3 Free-standing Filmscontrasting

confidence: 83%

Section: New Methods To Transfer Epitaxial Oxide Thin Filmsmentioning

confidence: 99%

High Yield Transfer of Clean Large-Area Epitaxial Oxide Thin Films

2021

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“…2D materials are defined as sheet-like solid crystals composed of a single or few atomic layers [2]. They are typically free-standing [22,39,40] and have a thickness of 1-10 Å. Ramesh et al define three types of thin-film architectures, including (i) single-phase epitaxial thin films, i.e., single-crystalline films having their growth orientation dictated by the orientation of a single-crystalline substrate material, (ii) horizontal heterostructures in which a magnetic phase is epitaxially interleaved with a ferroelectric (piezoelectric) phase and (iii) nanoscale 'vertical heterostructures' as the vertical analogue [16]. An additional subdivision into three classes, that can be prepared in the form of single-atom-or single-polyhedral-thick layers, is given by Butler et al [22]: (i) layered van der Waals solids contain individual layers bonded together by van der Waals forces, in which the atoms are covalently or ionically bonded, (ii) layered ionic solids represent crystal structures consisting of charged 2D polyhedral layers held together by ionic bonding, and (iii) multilayer assemblies produced by electrostatic layer-by-layer deposition or self-assembly processes.…”

Section: D Materialsmentioning

confidence: 99%

“…The wide range of properties results from the high flexibility of the chemical composition due to incorporation of different cations [83]. Since crystalline orientation and perovskite properties are closely related [39], physical characteristics such as the band structure, electron and hole transport properties, photoluminescence and dielectric behaviour may be affected by the degrees of tilting of the octahedra [151,152], the influence of strain relaxation or the preparation of free-standing thin films [39]. For instance, orientation-dependent ferroelectric and magnetic anisotropy have been detected in bulk BiFeO 3 [153] and SrRuO 3 [154,155].…”

Section: Perovskitesmentioning

confidence: 99%

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Oxidic 2D Materials

Dubnack

Müller

2021

Materials

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The possibility of producing stable thin films, only a few atomic layers thick, from a variety of materials beyond graphene has led to two-dimensional (2D) materials being studied intensively in recent years. By reducing the layer thickness and approaching the crystallographic monolayer limit, a variety of unexpected and technologically relevant property phenomena were observed, which also depend on the subsequent arrangement and possible combination of individual layers to form heterostructures. These properties can be specifically used for the development of multifunctional devices, meeting the requirements of the advancing miniaturization of modern manufacturing technologies and the associated need to stabilize physical states even below critical layer thicknesses of conventional materials in the fields of electronics, magnetism and energy conversion. Differences in the structure of potential two-dimensional materials result in decisive influences on possible growth methods and possibilities for subsequent transfer of the thin films. In this review, we focus on recent advances in the rapidly growing field of two-dimensional materials, highlighting those with oxidic crystal structure like perovskites, garnets and spinels. In addition to a selection of well-established growth techniques and approaches for thin film transfer, we evaluate in detail their application potential as free-standing monolayers, bilayers and multilayers in a wide range of advanced technological applications. Finally, we provide suggestions for future developments of this promising research field in consideration of current challenges regarding scalability and structural stability of ultra-thin films.

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A Generic Sacrificial Layer for Wide‐Range Freestanding Oxides with Modulated Magnetic Anisotropy

Peng

Yang

et al. 2022

Adv Funct Materials

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Freestanding oxide nanomembranes have promising applications because of their novel electronic states and flexible crystalline structures. Several materials have been developed as sacrificial layers to exfoliate thin films from substrates via wet-etching. However, these materials face great challenges in terms of either complicated crystalline structures or corrosive solutions. Here, a new sacrificial material, SrCoO 2.5 , is presented, which can be coherently grown with wide-range strains and crystalline orientations and is also soluble in eco-friendly solutions such as acetic acid, vinegar, and even carbonated drinks. With SrCoO 2.5 as the sacrificial layer, high-quality freestanding ferromagnetic SrRuO 3 membranes are achieved from wide-range epitaxial strains and different crystalline orientations. By investigating the evolution of the magnetic properties of these samples, it is discovered that epitaxial strain causes a distinct modification of the magnetic anisotropy of (001) pc -oriented SrRuO 3 samples, while its influence on the (110) pc and (111) pc samples is insignificant. This study not only demonstrates the freestanding SrRuO 3 as a promising material for flexible spintronic devices, but also offers a great opportunity to engineer a wide range of strained and oriented complex oxides for novel freestanding electronics using this newly developed sacrificial material.

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Synthesis of single-crystal La0.67Sr0.33MnO3 freestanding films with different crystal-orientation

Cited by 38 publications

References 32 publications

High Yield Transfer of Clean Large-Area Epitaxial Oxide Thin Films

High Yield Transfer of Clean Large-Area Epitaxial Oxide Thin Films

Oxidic 2D Materials

A Generic Sacrificial Layer for Wide‐Range Freestanding Oxides with Modulated Magnetic Anisotropy

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