Identifying Ionic and Electronic Charge Transfer at Oxide Heterointerfaces

Rose, Marc‐André; Vorokhta, Mykhailo; Slipukhina, Ivetta; Andrä, Michael; Bluhm, Hendrik; Duchoň, Tomáš; Ležaić, Marijana; Chambers, Scott A.; Dittmann, Regina; Mueller, David N.; Gunkel, Felix

doi:10.1002/adma.202004132

Cited by 27 publications

(19 citation statements)

References 89 publications

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“…[20,44,47] Therefore, establishing tunable strains and strain gradients in complex oxides via reconfiguration-driven assembly is a viable approach to tailor ionic and electronic transports in oxide-based devices on conventional semiconductor substrates. [48,49]…”

Section: Assembly and Strain Fields In Srtio 3 /Laalo 3 Nanomembranesmentioning

confidence: 99%

Reconfiguration of Amorphous Complex Oxides: A Route to a Broad Range of Assembly Phenomena, Hybrid Materials, and Novel Functionalities

Prakash

Chen

Debasu

et al. 2021

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materials that are freestanding either at a stage in their fabrication, in their final state, or both. [1] NMs with thicknesses in the range of a few nanometers to a few hundred nanometers can be isolated from their substrates through synthesis and processing techniques that have become established in the last 20 years. [1][2][3][4][5] The lateral dimensions of NMs are at least two orders of magnitude larger than their thickness, making them a distinctive platform from 0D, 1D, and bulk materials. [6] NMs enable a vast range of possibilities, including i) the capability to subject materials to elastic strain fields with magnitudes or geometries that are not realizable in bulk materials or by direct growth; [7][8][9] ii) unique and rapid characterization of materials properties and kinetic processes; [10,11] iii) heterogeneous integration of materials via controlled transfer, including, into environments in which the NM materials would be otherwise inaccessible via synthesis; [12,13] iv) 3D structures that can be processed in parallel on large-area substrates and can find use in several applications. [14][15][16][17][18] The scope of applications and phenomena that benefit from NMs can be extended to a new spectrum of materials Reconfiguration of amorphous complex oxides provides a readily controllable source of stress that can be leveraged in nanoscale assembly to access a broad range of 3D geometries and hybrid materials. An amorphous SrTiO 3 layer on a Si:B/Si 1−x Ge x :B heterostructure is reconfigured at the atomic scale upon heating, exhibiting a change in volume of ≈2% and accompanying biaxial stress. The Si:B/Si 1−x Ge x :B bilayer is fabricated by molecular beam epitaxy, followed by sputter deposition of SrTiO 3 at room temperature. The processes yield a hybrid oxide/semiconductor nanomembrane. Upon release from the substrate, the nanomembrane rolls up and has a curvature determined by the stress in the epitaxially grown Si:B/Si 1−x Ge x :B heterostructure. Heating to 600 °C leads to a decrease of the radius of curvature consistent with the development of a large compressive biaxial stress during the reconfiguration of SrTiO 3 . The control of stresses via post-deposition processing provides a new route to the assembly of complex-oxide-based heterostructures in 3D geometry. The reconfiguration of metastable mechanical stressors enables i) synthesis of various types of strained superlattice structures that cannot be fabricated by direct growth and ii) technologies based on strain engineering of complex oxides via highly scalable lithographic processes and on large-area semiconductor substrates.The ORCID identification number(s) for the author(s) of this article can be found under https://doi.org/10.1002/smll.202105424.

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Section: Assembly and Strain Fields In Srtio 3 /Laalo 3 Nanomembranesmentioning

confidence: 99%

Reconfiguration of Amorphous Complex Oxides: A Route to a Broad Range of Assembly Phenomena, Hybrid Materials, and Novel Functionalities

Prakash

Chen

Debasu

et al. 2021

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“…12,23 On the other hand, the creation of Sr vacancies (V Sr ) is also known to occur under oxygen rich PLD conditions. 2,24,25 Under the presence of oxygen species on the SrTiO 3 surface, Sr atoms make surface migration to form SrO oxide at a cost of electrons in the subsurface region, i.e., formation of an electron depletion layer near the surface. 2,24,26,27 In the case of V Sr formation, the surface resistance increases, affecting the electrical properties of the interfacial layer.…”

Section: Introductionmentioning

confidence: 99%

“…2,24,25 Under the presence of oxygen species on the SrTiO 3 surface, Sr atoms make surface migration to form SrO oxide at a cost of electrons in the subsurface region, i.e., formation of an electron depletion layer near the surface. 2,24,26,27 In the case of V Sr formation, the surface resistance increases, affecting the electrical properties of the interfacial layer. In fact, both types of V O or V Sr can occur simultaneously during the PLD process in which an oxygen environment and elevated temperature are required.…”

Section: Introductionmentioning

confidence: 99%

Nature of the surface space charge layer on undoped SrTiO₃(001)

et al. 2021

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“…Besides the polar catastrophe mechanism, the ionic aspect of the interface plays an important role in its electronic properties [57]. Interdiffusion and intermixing of atoms across the interface [58] and oxygen vacancies [59][60][61] can account for the 2DEG formation via various ionic doping mechanisms.…”

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Harnessing Conductive Oxide Interfaces for Resistive Random-Access Memories

Kvatinsky

Kornblum

2021

Front. Phys.

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Two-dimensional electron gases (2DEGs) can be formed at some oxide interfaces, providing a fertile ground for creating extraordinary physical properties. These properties can be exploited in various novel electronic devices such as transistors, gas sensors, and spintronic devices. Recently several works have demonstrated the application of 2DEGs for resistive random-access memories (RRAMs). We briefly review the basics of oxide 2DEGs, emphasizing scalability and maturity and describing a recent trend of progression from epitaxial oxide interfaces (such as LaAlO3/SrTiO3) to simple and highly scalable amorphous-polycrystalline systems (e.g., Al2O3/TiO2). We critically describe and compare recent RRAM devices based on these systems and highlight the possible advantages and potential of 2DEGs systems for RRAM applications. We consider the immediate challenges to revolve around scaling from one device to large arrays, where further progress with series resistance reduction and fabrication techniques needs to be made. We conclude by laying out some of the opportunities presented by 2DEGs based RRAM, including increased tunability and design flexibility, which could, in turn, provide advantages for multi-level capabilities.

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Identifying Ionic and Electronic Charge Transfer at Oxide Heterointerfaces

Cited by 27 publications

References 89 publications

Reconfiguration of Amorphous Complex Oxides: A Route to a Broad Range of Assembly Phenomena, Hybrid Materials, and Novel Functionalities

Reconfiguration of Amorphous Complex Oxides: A Route to a Broad Range of Assembly Phenomena, Hybrid Materials, and Novel Functionalities

Nature of the surface space charge layer on undoped SrTiO₃(001)

Harnessing Conductive Oxide Interfaces for Resistive Random-Access Memories

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Identifying Ionic and Electronic Charge Transfer at Oxide Heterointerfaces

Cited by 27 publications

References 89 publications

Reconfiguration of Amorphous Complex Oxides: A Route to a Broad Range of Assembly Phenomena, Hybrid Materials, and Novel Functionalities

Reconfiguration of Amorphous Complex Oxides: A Route to a Broad Range of Assembly Phenomena, Hybrid Materials, and Novel Functionalities

Nature of the surface space charge layer on undoped SrTiO3(001)

Harnessing Conductive Oxide Interfaces for Resistive Random-Access Memories

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Nature of the surface space charge layer on undoped SrTiO₃(001)