A magnetically-induced Coulomb gap in graphene due to electron-electron interactions
Insights into the fundamental properties of graphene’s Dirac-Weyl fermions have emerged from studies of electron tunnelling transistors in which an atomically thin layer of hexagonal boron nitride (hBN) is sandwiched between two layers of high purity graphene. Here, we show that when a single defect is present within the hBN tunnel barrier, it can inject electrons into the graphene layers and its sharply defined energy level acts as a high resolution spectroscopic probe of electron-electron interactions in graphene. We report a magnetic field dependent suppression of the tunnel current flowing through a single defect below temperatures of ~2 K. This is attributed to the formation of a magnetically-induced Coulomb gap in the spectral density of electrons tunnelling into graphene due to electron-electron interactions.
Funding
Van der Waals Heterostructures of 2D Materials
Engineering and Physical Sciences Research Council
Find out more...Quantum dynamics of electrons in emerging van der Waals devices
Engineering and Physical Sciences Research Council
Find out more...Horizon 2020 EC-FET Core 3 European Graphene Flagship Project
EC-FET Quantum Flagship Project 2D-SIPC
Lloyd Register Foundation Nanotechnology Grant
Ministry of Education, Singapore, under its Research Centre of Excellence award to the Institute for Functional Intelligent Materials (I-FIM, project No. EDUNC-33-18-279-V12)
Royal Society (UK, grant number RSRP\R\190000)
Russian Ministry of Science and Higher Education (Grant No. 075-01304-23-00)
History
School
- Science
Department
- Physics
Published in
Communications PhysicsVolume
6Issue
1Publisher
Springer NatureVersion
- VoR (Version of Record)
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© The AuthorsPublisher statement
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2023-06-19Publication date
2023-06-30Copyright date
2023eISSN
2399-3650Publisher version
Language
- en