Making Use of Si Contaminants during Chemical Vapor Deposition of Graphene on Cu: Synthesis of a Stable Material with the Textbook-like Band Structure of Free-Standing Graphene

Making Use of Si Contaminants during Chemical Vapor Deposition of Graphene on Cu: Synthesis of a Stable Material with the Textbook-like Band Structure of Free-Standing Graphene

We report on a gentle procedure for the complete electronic decoupling of graphene from Cu. The procedure can be added to the growth protocol of graphene synthesis by chemical vapor deposition making use of the widely unnoticed silicon release from hot wall quartz tube reactors. So far, Si release w...

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Bibliografiset tiedot
Päätekijä: Tim Kratky (7296743) (author)
Muut tekijät: Jürgen Kraus (11140090) (author), Paul M. Leidinger (20439207) (author), Patrick Zeller (1658965) (author), Francesca Genuzio (3797128) (author), Alessandro Sala (1535278) (author), Tevfik Onur Menteş (1535290) (author), Andrea Locatelli (1535287) (author), Sebastian Günther (1515196) (author)
Julkaistu: 2025
Aiheet:
Biochemistry
Medicine
Cell Biology
Statistics
Environmental Sciences not elsewhere classified
Chemical Sciences not elsewhere classified
Information Systems not elsewhere classified
subsequent oxygen exposure
replica bands due
like band structure
electronically noninteracting layers
electronic band structure
complete electronic decoupling
combined spectroscopic photoelectron
chemical vapor deposition
band gap formation
thicker graphene leads
graphene decouples electronically
standing graphene emerges
loaded cu foil
standing graphene
energy gap
polycrystalline foil
foil pretreatment
grown graphene
covering graphene
stable material
resolved photoemission
reactor turns
reactor segregates
making use
growth protocol
alternating stacking
4 ev
3 ev
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Yhteenveto:We report on a gentle procedure for the complete electronic decoupling of graphene from Cu. The procedure can be added to the growth protocol of graphene synthesis by chemical vapor deposition making use of the widely unnoticed silicon release from hot wall quartz tube reactors. So far, Si release was observed if the effect was large, so that it deteriorates the grown graphene. However, the effect can also be used to turn the electronic band structure of CVD-grown graphene on Cu into that of free-standing graphene as shown in a combined spectroscopic photoelectron and low energy electron microscopy study. Adding a foil pretreatment to the synthesis protocol in the reactor turns the polycrystalline foil into (111)-textured Cu, and the electronic band structure of CVD-grown graphene on Cu(111) is achieved with n-doping by −0.4 eV and band gap formation of 0.3 eV. If, however, graphene is synthesized on a Si-loaded Cu foil, subsequent oxygen exposure in the reactor segregates the dissolved Si to the surface and converts it to intercalated silica without destroying the covering graphene. The graphene decouples electronically, and the textbook-like electronic band structure of free-standing graphene emerges. The alternating stacking of 30°-rotated layers in thicker graphene leads to electronically noninteracting layers. Moreover, in angle-resolved photoemission, replica bands due to Umklapp processes emerge without the opening of an energy gap.

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