Capturing the Dynamics of Ti Diffusion Across Ti<sub>x</sub>W<sub>1−x</sub>/Cu Heterostructures using X‐Ray Photoelectron Spectroscopy

Kalha, Curran; Thakur, P.; Lee, Tien‐Lin; Reisinger, Michael; Zechner, Johannes; Nelhiebel, Michael; Regoutz, Anna

doi:10.1002/apxr.202300008

Advanced Physics Research

2023

DOI: 10.1002/apxr.202300008

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Capturing the Dynamics of Ti Diffusion Across Ti_xW_1−x/Cu Heterostructures using X‐Ray Photoelectron Spectroscopy

Curran Kalha

P. Thakur

Tien‐Lin Lee

et al.

Abstract: Interdiffusion phenomena between adjacent materials are highly prevalent in semiconductor device architectures and can present a major reliability challenge for the industry. To fully capture these phenomena, experimental approaches must go beyond static and post‐mortem studies to include in situ and in‐operando setups. Here, soft and hard X‐ray photoelectron spectroscopy (SXPS and HAXPES) is used to monitor diffusion in real‐time across a proxy device. The device consists of a Si/SiO2/TixW1−x(300 nm)/Cu(25 nm… Show more

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Enabling 2D Electron Gas with High Room‐Temperature Electron Mobility Exceeding 100 cm² Vs⁻¹ at a Perovskite Oxide Interface

Hoffmann,

Zupancic,

Riaz

et al. 2024

Advanced Materials

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In perovskite oxide heterostructures, bulk functional properties coexist with emergent physical phenomena at epitaxial interfaces. Notably, charge transfer at the interface between two insulating oxide layers can lead to the formation of a 2D electron gas (2DEG) with possible applications in, e.g., high‐electron‐mobility transistors and ferroelectric field‐effect transistors. So far, the realization of oxide 2DEGs is, however, largely limited to the interface between the single‐crystal substrate and epitaxial film, preventing their deliberate placement inside a larger device architecture. Additionally, the substrate‐limited quality of perovskite oxide interfaces hampers room‐temperature (RT) 2DEG performance due to notoriously low electron mobility. In this work, the controlled creation of an interfacial 2DEG at the epitaxial interface between perovskite oxides BaSnO3 and LaInO3 is demonstrated with enhanced RT electron mobility values up to 119 cm2 Vs−1—the highest RT value reported so far for a perovskite oxide 2DEG. Using a combination of state‐of‐the‐art deposition modes during oxide molecular beam epitaxy, this approach opens up another degree of freedom in optimization and in situ control of the interface between two epitaxial oxide layers away from the substrate interface. Thus this approach is expected to apply to the general class of perovskite oxide 2DEG systems and to enable their improved compatibility with novel device concepts and integration across materials platforms.

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Enabling 2D Electron Gas with High Room‐Temperature Electron Mobility Exceeding 100 cm² Vs⁻¹ at a Perovskite Oxide Interface

Hoffmann,

Zupancic,

Riaz

et al. 2024

Advanced Materials

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show abstract

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Capturing the Dynamics of Ti Diffusion Across Ti_xW_1−x/Cu Heterostructures using X‐Ray Photoelectron Spectroscopy

Cited by 1 publication

References 79 publications

Enabling 2D Electron Gas with High Room‐Temperature Electron Mobility Exceeding 100 cm² Vs⁻¹ at a Perovskite Oxide Interface

Enabling 2D Electron Gas with High Room‐Temperature Electron Mobility Exceeding 100 cm² Vs⁻¹ at a Perovskite Oxide Interface

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Capturing the Dynamics of Ti Diffusion Across TixW1−x/Cu Heterostructures using X‐Ray Photoelectron Spectroscopy

Cited by 1 publication

References 79 publications

Enabling 2D Electron Gas with High Room‐Temperature Electron Mobility Exceeding 100 cm2 Vs−1 at a Perovskite Oxide Interface

Enabling 2D Electron Gas with High Room‐Temperature Electron Mobility Exceeding 100 cm2 Vs−1 at a Perovskite Oxide Interface

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Product

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Capturing the Dynamics of Ti Diffusion Across Ti_xW_1−x/Cu Heterostructures using X‐Ray Photoelectron Spectroscopy

Enabling 2D Electron Gas with High Room‐Temperature Electron Mobility Exceeding 100 cm² Vs⁻¹ at a Perovskite Oxide Interface

Enabling 2D Electron Gas with High Room‐Temperature Electron Mobility Exceeding 100 cm² Vs⁻¹ at a Perovskite Oxide Interface