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dc.contributor.authorBradford, Jonathan
dc.contributor.otherRahman, Kazi
dc.contributor.otherFelton, James
dc.contributor.otherCheng, Tin
dc.contributor.otherShiffa, Mustaqeem
dc.contributor.otherBeton, Peter
dc.contributor.otherSaywell, Alex
dc.contributor.otherGreenaway, Mark
dc.contributor.otherNovikov, Sergei
dc.contributor.otherO'Shea, James
dc.contributor.otherpatane, amalia
dc.date.accessioned2024-11-22T10:16:39Z
dc.date.available2024-11-22T10:16:39Z
dc.date.issued2024-11-22
dc.identifier.urihttps://rdmc.nottingham.ac.uk/handle/internal/11646
dc.description.abstractOriginal data for the Owing to their atomically thin nature, structural defects in two dimensional materials often play a dominating role in their electronic and optical properties. Here, we grow epitaxial GaSe monolayers on graphene/SiC by molecular beam epitaxy and characterise the layers by in situ scanning tunnelling microscopy and angle-resolved photoemission spectroscopy extracted from k-resolved photoemission electron microscopy mapping. We identify an electric dipole at the GaSe/graphene interface, with electrons accumulating on the GaSe, that cannot be compensated by p-type doping through the creation of defects formed by annealing in ultrahigh vacuum. Additionally, we demonstrate that both as-grown and defective GaSe layers are remarkably resilient to oxidation in a pure O2 environment, and chemisorption of O2 molecules on the surface can effectively electronically neutralise the doping in the layer. This work demonstrates the robust interlayer interaction in the GaSe/graphene van der Waals heterostructure and the role of defects on the doping for nanoelectronics.en_UK
dc.language.isoenen_UK
dc.publisherThe University of Nottinghamen_UK
dc.rightsCC-BY*
dc.rights.urihttps://creativecommons.org/licenses/by/4.0/*
dc.subject.lcshMolecular beam epitaxyen_UK
dc.subject.lcshCrystal growthen_UK
dc.subject.lcshLayer structure (Solids)en_UK
dc.subject.lcshTwo-dimensional materialsen_UK
dc.titleDefect-Induced Doping and Chemisorption of O2 in Se Deficient GaSe Monolayersen_UK
dc.typeDataseten_UK
dc.identifier.doihttp://doi.org/10.17639/nott.7495
dc.subject.freegallium selenide, in situ characterisation, molecular beam epitaxy, STM, ARPES, van der Waals epitaxyen_UK
dc.subject.jacsPhysical sciences::Physicsen_UK
dc.subject.lcQ Science::QC Physics::QC170 Atomic physics. Constitution and properties of matteren_UK
dc.date.collection2023en_UK
uon.divisionUniversity of Nottingham, UK Campus::Faculty of Science::School of Physics and Astronomyen_UK
uon.funder.controlledEngineering & Physical Sciences Research Councilen_UK
uon.datatypeScanning tunnelling microscopy images and photoemission spectraen_UK
uon.funder.freeRoyal Societyen_UK
uon.grantEP/T019018/1en_UK
uon.grantEP/V05323X/1en_UK
uon.grantEP/V008110/1en_UK
uon.grantEP/W035510/1en_UK
uon.collectionmethodScanning tunnelling microscopy, photoemission spectroscopyen_UK


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