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Anderson transition in stoichiometric Fe2VAl: high thermoelectric performance from impurity bands

Author

Listed:
  • Fabian Garmroudi

    (TU Wien)

  • Michael Parzer

    (TU Wien)

  • Alexander Riss

    (TU Wien)

  • Andrei V. Ruban

    (KTH Royal Institute of Technology
    Materials Center Leoben Forschung GmbH)

  • Sergii Khmelevskyi

    (TU Wien)

  • Michele Reticcioli

    (Universität Wien)

  • Matthias Knopf

    (TU Wien)

  • Herwig Michor

    (TU Wien)

  • Andrej Pustogow

    (TU Wien)

  • Takao Mori

    (National Institute for Materials Science
    University of Tsukuba)

  • Ernst Bauer

    (TU Wien)

Abstract

Discovered more than 200 years ago in 1821, thermoelectricity is nowadays of global interest as it enables direct interconversion of thermal and electrical energy via the Seebeck/Peltier effect. In their seminal work, Mahan and Sofo mathematically derived the conditions for ’the best thermoelectric’—a delta-distribution-shaped electronic transport function, where charge carriers contribute to transport only in an infinitely narrow energy interval. So far, however, only approximations to this concept were expected to exist in nature. Here, we propose the Anderson transition in a narrow impurity band as a physical realisation of this seemingly unrealisable scenario. An innovative approach of continuous disorder tuning allows us to drive the Anderson transition within a single sample: variable amounts of antisite defects are introduced in a controlled fashion by thermal quenching from high temperatures. Consequently, we obtain a significant enhancement and dramatic change of the thermoelectric properties from p-type to n-type in stoichiometric Fe2VAl, which we assign to a narrow region of delocalised electrons in the energy spectrum near the Fermi energy. Based on our electronic transport and magnetisation experiments, supported by Monte-Carlo and density functional theory calculations, we present a novel strategy to enhance the performance of thermoelectric materials.

Suggested Citation

  • Fabian Garmroudi & Michael Parzer & Alexander Riss & Andrei V. Ruban & Sergii Khmelevskyi & Michele Reticcioli & Matthias Knopf & Herwig Michor & Andrej Pustogow & Takao Mori & Ernst Bauer, 2022. "Anderson transition in stoichiometric Fe2VAl: high thermoelectric performance from impurity bands," Nature Communications, Nature, vol. 13(1), pages 1-10, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-31159-w
    DOI: 10.1038/s41467-022-31159-w
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    References listed on IDEAS

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    1. Forman, Clemens & Muritala, Ibrahim Kolawole & Pardemann, Robert & Meyer, Bernd, 2016. "Estimating the global waste heat potential," Renewable and Sustainable Energy Reviews, Elsevier, vol. 57(C), pages 1568-1579.
    2. Kanishka Biswas & Jiaqing He & Ivan D. Blum & Chun-I Wu & Timothy P. Hogan & David N. Seidman & Vinayak P. Dravid & Mercouri G. Kanatzidis, 2012. "High-performance bulk thermoelectrics with all-scale hierarchical architectures," Nature, Nature, vol. 489(7416), pages 414-418, September.
    3. Pourkiaei, Seyed Mohsen & Ahmadi, Mohammad Hossein & Sadeghzadeh, Milad & Moosavi, Soroush & Pourfayaz, Fathollah & Chen, Lingen & Pour Yazdi, Mohammad Arab & Kumar, Ravinder, 2019. "Thermoelectric cooler and thermoelectric generator devices: A review of present and potential applications, modeling and materials," Energy, Elsevier, vol. 186(C).
    4. Li-Dong Zhao & Shih-Han Lo & Yongsheng Zhang & Hui Sun & Gangjian Tan & Ctirad Uher & C. Wolverton & Vinayak P. Dravid & Mercouri G. Kanatzidis, 2014. "Ultralow thermal conductivity and high thermoelectric figure of merit in SnSe crystals," Nature, Nature, vol. 508(7496), pages 373-377, April.
    5. Jong-Soo Rhyee & Kyu Hyoung Lee & Sang Mock Lee & Eunseog Cho & Sang Il Kim & Eunsung Lee & Yong Seung Kwon & Ji Hoon Shim & Gabriel Kotliar, 2009. "Peierls distortion as a route to high thermoelectric performance in In4Se3-δ crystals," Nature, Nature, vol. 459(7249), pages 965-968, June.
    6. Allon I. Hochbaum & Renkun Chen & Raul Diaz Delgado & Wenjie Liang & Erik C. Garnett & Mark Najarian & Arun Majumdar & Peidong Yang, 2008. "Enhanced thermoelectric performance of rough silicon nanowires," Nature, Nature, vol. 451(7175), pages 163-167, January.
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