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Emergent interface vibrational structure of oxide superlattices

Author

Listed:
  • Eric R. Hoglund

    (University of Virginia)

  • De-Liang Bao

    (Vanderbilt University)

  • Andrew O’Hara

    (Vanderbilt University)

  • Sara Makarem

    (University of Virginia)

  • Zachary T. Piontkowski

    (Sandia National Laboratories)

  • Joseph R. Matson

    (Vanderbilt University)

  • Ajay K. Yadav

    (University of California Berkley)

  • Ryan C. Haislmaier

    (Pennsylvania State University)

  • Roman Engel-Herbert

    (Paul-Drude-Institut für Festkörperelektronik
    Institut für Physik, Humboldt-Universität zu Berlin)

  • Jon F. Ihlefeld

    (University of Virginia)

  • Jayakanth Ravichandran

    (University of Southern California)

  • Ramamoorthy Ramesh

    (University of California Berkley)

  • Joshua D. Caldwell

    (Vanderbilt University)

  • Thomas E. Beechem

    (Sandia National Laboratories
    Sandia National Laboratories
    Purdue University)

  • John A. Tomko

    (University of Virginia)

  • Jordan A. Hachtel

    (Center for Nanophase Materials Sciences, Oak Ridge National Laboratory)

  • Sokrates T. Pantelides

    (Vanderbilt University
    Vanderbilt University)

  • Patrick E. Hopkins

    (University of Virginia
    University of Virginia
    University of Virginia)

  • James M. Howe

    (University of Virginia)

Abstract

As the length scales of materials decrease, the heterogeneities associated with interfaces become almost as important as the surrounding materials. This has led to extensive studies of emergent electronic and magnetic interface properties in superlattices1–9. However, the interfacial vibrations that affect the phonon-mediated properties, such as thermal conductivity10,11, are measured using macroscopic techniques that lack spatial resolution. Although it is accepted that intrinsic phonons change near boundaries12,13, the physical mechanisms and length scales through which interfacial effects influence materials remain unclear. Here we demonstrate the localized vibrational response of interfaces in strontium titanate–calcium titanate superlattices by combining advanced scanning transmission electron microscopy imaging and spectroscopy, density functional theory calculations and ultrafast optical spectroscopy. Structurally diffuse interfaces that bridge the bounding materials are observed and this local structure creates phonon modes that determine the global response of the superlattice once the spacing of the interfaces approaches the phonon spatial extent. Our results provide direct visualization of the progression of the local atomic structure and interface vibrations as they come to determine the vibrational response of an entire superlattice. Direct observation of such local atomic and vibrational phenomena demonstrates that their spatial extent needs to be quantified to understand macroscopic behaviour. Tailoring interfaces, and knowing their local vibrational response, provides a means of pursuing designer solids with emergent infrared and thermal responses.

Suggested Citation

  • Eric R. Hoglund & De-Liang Bao & Andrew O’Hara & Sara Makarem & Zachary T. Piontkowski & Joseph R. Matson & Ajay K. Yadav & Ryan C. Haislmaier & Roman Engel-Herbert & Jon F. Ihlefeld & Jayakanth Ravic, 2022. "Emergent interface vibrational structure of oxide superlattices," Nature, Nature, vol. 601(7894), pages 556-561, January.
  • Handle: RePEc:nat:nature:v:601:y:2022:i:7894:d:10.1038_s41586-021-04238-z
    DOI: 10.1038/s41586-021-04238-z
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    Citations

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    Cited by:

    1. Ruochen Shi & Qize Li & Xiaofeng Xu & Bo Han & Ruixue Zhu & Fachen Liu & Ruishi Qi & Xiaowen Zhang & Jinlong Du & Ji Chen & Dapeng Yu & Xuetao Zhu & Jiandong Guo & Peng Gao, 2024. "Atomic-scale observation of localized phonons at FeSe/SrTiO3 interface," Nature Communications, Nature, vol. 15(1), pages 1-7, December.
    2. Mahmut S. Kavrik & Jordan A. Hachtel & Wonhee Ko & Caroline Qian & Alex Abelson & Eyup B. Unlu & Harshil Kashyap & An-Ping Li & Juan C. Idrobo & Matt Law, 2022. "Emergence of distinct electronic states in epitaxially-fused PbSe quantum dot superlattices," Nature Communications, Nature, vol. 13(1), pages 1-9, December.
    3. Hailing Jiang & Tao Wang & Zhenyu Zhang & Fang Liu & Ruochen Shi & Bowen Sheng & Shanshan Sheng & Weikun Ge & Ping Wang & Bo Shen & Bo Sun & Peng Gao & Lucas Lindsay & Xinqiang Wang, 2024. "Atomic-scale visualization of defect-induced localized vibrations in GaN," Nature Communications, Nature, vol. 15(1), pages 1-9, December.
    4. Kejun Hu & Qing Li & Dongsheng Song & Yingze Jia & Zhiyao Liang & Shuai Wang & Haifeng Du & Hai-Hu Wen & Binghui Ge, 2024. "Atomic scale disorder and reconstruction in bulk infinite-layer nickelates lacking superconductivity," Nature Communications, Nature, vol. 15(1), pages 1-9, December.
    5. Xuexi Yan & Yixiao Jiang & Qianqian Jin & Tingting Yao & Weizhen Wang & Ang Tao & Chunyang Gao & Xiang Li & Chunlin Chen & Hengqiang Ye & Xiu-Liang Ma, 2023. "Interfacial interaction and intense interfacial ultraviolet light emission at an incoherent interface," Nature Communications, Nature, vol. 14(1), pages 1-7, December.

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