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Gaps tunable by electrostatic gates in strained graphene
T. Low
, F. Guinea, M. I. Katsnelson
Electrical and Computer Engineering
Research output
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Contribution to journal
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Article
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peer-review
105
Scopus citations
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Physics & Astronomy
superlattices
80%
graphene
69%
electrostatics
64%
scalars
61%
geometry
47%
electric potential
45%
electronics
44%
wavelengths
40%
Engineering & Materials Science
Graphene
100%
Electrostatics
90%
Superlattices
79%
Energy gap
48%
Wavelength
37%
Geometry
25%
Electric potential
21%
Experiments
15%
Chemical Compounds
Graphene
60%
Strain
59%
Electric Potential
55%
Superlattice
43%
Band Gap
31%