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Author
dc.contributor.author
Robinson, BJ 
Author
dc.contributor.author
Bailey, SWD 
Author
dc.contributor.author
O'Driscoll, LJ 
Author
dc.contributor.author
Visontai, D 
Author
dc.contributor.author
Welsh, DJ 
Author
dc.contributor.author
Mostert, AB 
Author
dc.contributor.author
Mazzocco, R 
Author
dc.contributor.author
Rabot, C 
Author
dc.contributor.author
Jarvis, SP 
Author
dc.contributor.author
Kolosov, OV 
Availability Date
dc.date.accessioned
2022-07-22T08:29:57Z
Availability Date
dc.date.available
2022-07-22T08:29:57Z
Release
dc.date.issued
2017
uri
dc.identifier.uri
http://hdl.handle.net/10831/67147
Abstract
dc.description.abstract
Graphene and related two-dimensional (2D) materials possess outstanding electronic and mechanical properties, chemical stability, and high surface area. However, to realize graphene's potential for a range of applications in materials science and nanotechnology there is a need to understand and control the interaction of graphene with tailored high-performance surfactants designed to facilitate the preparation, manipulation, and functionalization of new graphene systems. Here we report a combined experimental and theoretical study of the surface structure and dynamics on graphene of pyrene-oligo ethylene glycol (OEG)-based surfactants, which have previously been shown to disperse carbon nanotubes in water. Molecular self-assembly of the surfactants on graphitic surfaces is experimentally monitored and optimized using a graphene coated quartz crystal microbalance in ambient and vacuum environments. Real-space nanoscale resolution nanomechanical and topographical mapping of submonolayer surfactant coverage, using ultrasonic and atomic force microscopies both in ambient and ultrahigh vacuum, reveals complex, multilength-scale self-assembled structures. Molecular dynamics simulations show that at the nanoscale these structures, on atomically flat graphitic surfaces, are dependent upon the surfactant OEG chain length and are predicted to display a previously unseen class of 2D self-arranged "starfish" micelles (2DSMs). While three-dimensional micelles are well-known for their widespread uses ranging from microreactors to drug-delivery vehicles, these 2DSMs possess the highly desirable and tunable characteristics of high surface affinity coupled with unimpeded mobility, opening up strategies for processing and functionalizing 2D materials.
Language
dc.language
Angol

dc.rights
Nevezd meg! CC BY

dc.rights.uri
https://creativecommons.org/licenses/by/4.0/
Title
dc.title
Formation of Two-Dimensional Micelles on Graphene: Multi-Scale Theoretical and Experimental Study
Type
dc.type
folyóiratcikk
Date Change
dc.date.updated
2022-05-16T10:06:08Z
Note
dc.description.note
Department of Physics, Lancaster University, Lancaster, LA1 4YB, United Kingdom Materials Science Institute, Lancaster University, Lancaster, LA1 4YW, United Kingdom Department of Chemistry, Durham University, Durham, DH1 3LE, United Kingdom CEA, LETI 17 Rue des Martyrs, Grenoble, 38054, France School of Physics and Astronomy, University of Nottingham, Nottingham, NG7 2RD, United Kingdom Department of Physics of Complex Systems, Eötvös University, Pázmány Péter Sétány 1/A, Budapest, H-1117, Hungary Cited By :5 Export Date: 21 October 2019 Correspondence Address: Robinson, B.J.; Department of Physics, Lancaster UniversityUnited Kingdom; email: b.j.robinson@lancaster.ac.uk
Scope
dc.format.page
3404-3412
Doi ID
dc.identifier.doi
10.1021/acsnano.7b01071
Wos ID
dc.identifier.wos
000398014900107
ID Scopus
dc.identifier.scopus
85016398379
MTMT ID
dc.identifier.mtmt
3411415
Issue Number
dc.identifier.issue
3
abbreviated journal
dc.identifier.jabbrev
ACS NANO
Journal
dc.identifier.jtitle
ACS NANO
Volume Number
dc.identifier.volume
11
Release Date
dc.description.issuedate
2017
Pubmed ID
dc.identifier.pubmed
28282115
department of Author
dc.contributor.institution
TTK hallgatók
department of Author
dc.contributor.institution
Anyagfizikai Tanszék
department of Author
dc.contributor.institution
Komplex Rendszerek Fizikája Tanszék
Author institution
dc.contributor.department
Komplex Rendszerek Fizikája Tanszék


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Formation of Two-Dimensional Micelles on Graphene: Multi-Scale Theoretical and Experimental Study
 

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