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Kondo effect in a single-electron transistor

Author

Listed:
  • D. Goldhaber-Gordon

    (Massachusetts Institute of Technology
    Braun Center for Submicron Research, Weizmann Institute of Science)

  • Hadas Shtrikman

    (Braun Center for Submicron Research, Weizmann Institute of Science)

  • D. Mahalu

    (Braun Center for Submicron Research, Weizmann Institute of Science)

  • David Abusch-Magder

    (Massachusetts Institute of Technology)

  • U. Meirav

    (Braun Center for Submicron Research, Weizmann Institute of Science)

  • M. A. Kastner

    (Massachusetts Institute of Technology)

Abstract

How localized electrons interact with delocalized electrons is a central question to many problems in sold-state physics1,2,3. The simplest manifestation of this situation is the Kondo effect, which occurs when an impurity atom with an unpaired electron is placed in a metal2. At low temperatures a spin singlet state is formed between the unpaired localized electron and delocalized electrons at the Fermi energy. Theories predict4,5,6,7 that a Kondo singlet should form in a single-electron transistor (SET), which contains a confined ‘droplet’ of electrons coupled by quantum-mechanical tunnelling to the delocalized electrons in the transistor's leads. If this is so, a SET could provide a means of investigating aspects of the Kondo effect under controlled circumstances that are not accessible in conventional systems: the number of electrons can be changed from odd to even, the difference in energy between the localized state and the Fermi level can be tuned, the coupling to the leads can be adjusted, voltage differences can be applied to reveal non-equilibrium Kondo phenomena7, and a single localized state can be studied rather than a statistical distribution. But for SETs fabricated previously, the binding energy of the spin singlet has been too small to observe Kondo phenomena. Ralph and Buhrman8 have observed the Kondo singlet at a single accidental impurity in a metal point contact, but with only two electrodes and without control over the structure they were not able to observe all of the features predicted. Here we report measurements on SETs smaller than those made previously, which exhibit all of the predicted aspects of the Kondo effect in such a system.

Suggested Citation

  • D. Goldhaber-Gordon & Hadas Shtrikman & D. Mahalu & David Abusch-Magder & U. Meirav & M. A. Kastner, 1998. "Kondo effect in a single-electron transistor," Nature, Nature, vol. 391(6663), pages 156-159, January.
    • Handle: RePEc:nat:nature:v:391:y:1998:i:6663:d:10.1038_34373
    DOI: 10.1038/34373
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    Cited by:

    1. Kenji Shibata & Masaki Yoshida & Kazuhiko Hirakawa & Tomohiro Otsuka & Satria Zulkarnaen Bisri & Yoshihiro Iwasa, 2023. "Single PbS colloidal quantum dot transistors," Nature Communications, Nature, vol. 14(1), pages 1-8, December.
    2. Annika Kurzmann & Yaakov Kleeorin & Chuyao Tong & Rebekka Garreis & Angelika Knothe & Marius Eich & Christopher Mittag & Carolin Gold & Folkert Kornelis Vries & Kenji Watanabe & Takashi Taniguchi & Vl, 2021. "Kondo effect and spin–orbit coupling in graphene quantum dots," Nature Communications, Nature, vol. 12(1), pages 1-6, December.
    3. C. Piquard & P. Glidic & C. Han & A. Aassime & A. Cavanna & U. Gennser & Y. Meir & E. Sela & A. Anthore & F. Pierre, 2023. "Observing the universal screening of a Kondo impurity," Nature Communications, Nature, vol. 14(1), pages 1-11, December.

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