Synthesis and Electronic Structure of the Fractionally Occupied Double Perovskite EuTa_2O_6 with Ordered Europium Vacancies

Tobias Schwaigert ¹Ali Barooni ²Benjamin Gregory ³Paul Malinowski ⁴Anirudh Tenneti ¹Sonia Hasko ⁵Brenan Palazzolo ⁶Jeffrey W Hodgson ⁷Brendan Faeth ⁸Patrick M. Woodward ⁹Kyle M. Shen ³Andrej Singer ¹Maryam Ghazisaeidi ²Salva Salmani-Rezaie ²Darrell G. Schlom ¹⁰Kaveh Ahadi²

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作者信息

1. Department of Materials Science and Engineering Cornell University Ithaca,NY 14853,USA
2. Department of Materials Science and Engineering The Ohio State University Columbus,OH 43210,USA
3. Department of Physics Cornell University Ithaca,NY 14853,USA||Laboratory of Atomic and Solid State Physics Department of Physics Cornell University Ithaca,NY,USA
4. Department of Physics Cornell University Ithaca,NY 14853,USA
5. Platform for the Accelerated Realization,Analysis,and Discovery of Interface Materials(PARADIM)Cornell University Ithaca,NY 14853,USA||Department of Chemical and Biological Engineering Princeton University Princeton,NJ,USA
6. Platform for the Accelerated Realization,Analysis,and Discovery of Interface Materials(PARADIM)Cornell University Ithaca,NY 14853,USA||Department of Physics and Astronomy Clemson University Clemson,SC 29631,USA
7. Department of Materials Science and Engineering Cornell University Ithaca, NY 14853, USA
8. Platform for the Accelerated Realization,Analysis,and Discovery of Interface Materials(PARADIM)Cornell University Ithaca,NY 14853,USA
9. Department of Chemistry The Ohio State University Columbus,OH 43210,USA
10. Department of Materials Science and Engineering Cornell University Ithaca,NY 14853,USA||Kavli Institute at Cornell for Nanoscale Science Ithaca,NY 14853,USA||Leibniz-Institut fuer Kristallzuechtung Max-Born-Strasse 2,12489 Berlin,Germany
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Abstract

2D electronic states underline a wide range of exotic phenomena and provide potential for electronic devices. The ability to create and control these states often requires physical thinning or highly perfect interfaces. In this work, the "fractional double perovskite" ATa_2O_6 (A: Eu~(2+)) is synthesized and characterized, where alternating A-site cations and A-site vacancies significantly impact the electronic structure, giving rise to a quasi-2D electronic state within a 3D crystal framework. The intrinsic crystal anisotropy of ATa_2O_6 plays a pivotal role, underscoring how targeted structural modifications can facilitate the emergence of novel quantum states. Utilizing single-crystal synthesis via molecular-beam epitaxy, the crystal and electronic structures of ATa_2O_6 are investigated. X-ray diffraction and electron microscopy reveal the layered A-site ordering. Synchrotron-based diffraction shows the presence of three epitaxial twin variants of ATa_2O_6 domains, with preferential orientation along out-of-plane direction. Angle-resolved photoemission spectroscopy, along with density functional theory calculations, provide direct insight into the electronic structure, unveiling the potential for engineered confined states within bulk materials. These findings highlight ATa_2O_6 as a platform for studying 2D-like electronic phenomena in a 3D context, paving the way for novel device architectures.

Key words

2D electronics/double perovskite/EuTa_2O_6/fractional double perovskites/oxide molecular beam epitaxy

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出版年

2026

Advanced materials for optics and electronics

ISSN：1616-301X

参考文献量71

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