Self-assembly of mesoporous nanotubes assembled from interwoven ultrathin birnessite-type MnO2 nanosheets for asymmetric supercapacitorsMechanical properties of nanoparticle chain aggregates by combined AFM and SEM: isolated aggregates and networks.Raman measurements of thermal transport in suspended monolayer graphene of variable sizes in vacuum and gaseous environments.Growth of carbon nanowalls at atmospheric pressure for one-step gas sensor fabricationThermal transport in suspended and supported monolayer graphene grown by chemical vapor deposition.Unoxidized graphene/alumina nanocomposite: fracture- and wear-resistance effects of graphene on alumina matrix.The chemistry of graphene oxide.Synthesis of high quality monolayer graphene at reduced temperature on hydrogen-enriched evaporated copper (111) films.Large-area graphene single crystals grown by low-pressure chemical vapor deposition of methane on copper.Carbon-based supercapacitors produced by activation of graphene.Synthesis and characterization of large-area graphene and graphite films on commercial Cu-Ni alloy foils.Oxidative doping renders graphene hydrophilic, facilitating its use as a support in biological TEM.Selective-area fluorination of graphene with fluoropolymer and laser irradiation.Ultrathin graphite foam: a three-dimensional conductive network for battery electrodes.The role of surface oxygen in the growth of large single-crystal graphene on copper.2D materials. Graphene, related two-dimensional crystals, and hybrid systems for energy conversion and storage.Time, temperature, and load: the flaws of carbon nanotubes.Graphene-silica composite thin films as transparent conductors.Graphene-based ultracapacitors.Synthesis and solid-state NMR structural characterization of 13C-labeled graphite oxide.Colloidal suspensions of highly reduced graphene oxide in a wide variety of organic solvents.Large-area synthesis of high-quality and uniform graphene films on copper foils.Evolution of graphene growth on Ni and Cu by carbon isotope labeling.Transfer of large-area graphene films for high-performance transparent conductive electrodes.Revealing the planar chemistry of two-dimensional heterostructures at the atomic level.Laser-induced phase separation of silicon carbideStructurally driven one-dimensional electron confinement in sub-5-nm graphene nanowrinkles.Laser-Material Interactions for Flexible Applications.Stretchable and highly sensitive graphene-on-polymer strain sensors.Chemical methods for the production of graphenes.Graphene and graphene oxide: synthesis, properties, and applications.From conception to realization: an historial account of graphene and some perspectives for its future.Progress, challenges, and opportunities in two-dimensional materials beyond graphene.Reduced graphene oxide by chemical graphitization.Selective mechanical transfer of graphene from seed copper foil using rate effects.Metal contacts on physical vapor deposited monolayer MoS2.25 GHz embedded-gate graphene transistors with high-k dielectrics on extremely flexible plastic sheets.The physics and chemistry of graphene-on-surfaces.Toward the controlled synthesis of hexagonal boron nitride films.Biocompatible, robust free-standing paper composed of a TWEEN/graphene composite.
P50
Q30568952-8C4D1AFE-B173-4B02-96EB-99E09251BEF5Q33266289-264E0E90-B1F6-4661-9C95-E04253023CAAQ33448967-D94EEAAC-8379-47E6-B6BF-A1B41341ED85Q33451008-CF81CE72-D2C9-4EB0-9C8A-71DD23D9B5FCQ33560217-67920152-F995-46AE-96FC-4AFE744E9B3DQ33713467-B81A5C32-5A60-4110-9A0F-BDFDA9F91AB4Q34089120-5A7E462B-6D8E-4CCC-847E-4762F68C4F82Q34153112-0C3C42AB-17AA-4B3B-82DE-C8830C1AF539Q34163701-AB116BDC-06AE-477E-ACD9-AFC94E0BFF75Q34184678-E31E1028-C14D-4049-A1CE-B4427EB9124AQ34203891-D6787249-BEAE-4543-993A-48069B5D8120Q34215560-22B53683-8E76-4287-8E80-DE0294F79331Q34223929-A5337BA2-2851-420D-B42A-962A6B99EC44Q34270130-1A132204-17D2-424A-B6B9-EB30999C925AQ34380176-2CD536D5-EE8B-41EF-8F2C-A1467BDFDE14Q34456349-35951C95-A0D3-4985-BFA9-697C2A657857Q34598175-BD8159F4-E7CA-4508-9D33-E8FCA80DC25EQ34641887-74112F43-04D8-4FB8-B3A0-870CF3729F53Q34826406-B363EDD0-4C83-4D3F-8C78-EC09000681D0Q34837758-494E1E0C-9D1F-45AD-86F5-8E4CA3147B42Q34957793-B1407444-17CD-43A8-BC6A-C6EE187673C6Q34979745-A56CBEB6-8590-4782-AB64-5E20A498E59FQ34999844-9D4F3324-A59B-4C16-BADA-5E1C889EA108Q35008831-D872294F-89D2-44E0-B052-A3792A7AA97FQ36018576-A24092C8-04E3-4087-A3B1-3C22D8F4A77BQ36207610-6BA15A71-E8B0-4A5B-8D5D-F412C2ED03F7Q36265995-17425FD6-2E68-485B-A338-9A17D6049066Q36332591-44DA425F-206F-4418-A768-0F4EF58A74D3Q36403971-47C48F2C-C308-4624-B62D-E163B8C970DBQ37435911-4EC40FD5-923D-492A-A2F3-EB4C26E78F5FQ37779761-60511121-F6B5-414E-9173-C8CBA3DD1FCDQ37812591-A95DA953-95CD-4E31-AB38-A6D433E73678Q38086925-7B294F0A-C9E3-45AD-9867-606C9853254CQ38481388-D30B01D6-148E-41E6-A550-A6C196AD1BEAQ39043821-F0C47019-ACDB-4843-9E60-779BBCDF71CAQ39316901-893E3F41-FAA6-45E2-86AE-857FD9951A6BQ39367705-AF6DF5C8-67EB-445E-B943-78BE14070A68Q39415281-752DDABB-7BD5-469B-9C4C-30175D7FC0CBQ39602186-92C24E02-708D-454D-81C8-6E4FD2361F88Q39701050-95C14D43-DC59-4959-940F-D86F61C33581
P50
description
American scientist
@en
Amerikaans ingenieur
@nl
US-amerikanischer Chemiker (Nanotechnologie)
@de
ingeniero estadounidense
@es
inxenieru estauxunidense
@ast
nolavan Lamerikänik
@vo
siensiste american
@lfn
usona sciencisto
@eo
مهندس من الولايات المتحدة الأمريكية
@ar
name
Rodney S. Ruoff
@ast
Rodney S. Ruoff
@ca
Rodney S. Ruoff
@de
Rodney S. Ruoff
@en
Rodney S. Ruoff
@es
Rodney S. Ruoff
@fr
Rodney S. Ruoff
@nl
Rodney S. Ruoff
@sl
رادنی اس. روف
@azb
ロドニー・ルオフ
@ja
type
label
Rodney S. Ruoff
@ast
Rodney S. Ruoff
@ca
Rodney S. Ruoff
@de
Rodney S. Ruoff
@en
Rodney S. Ruoff
@es
Rodney S. Ruoff
@fr
Rodney S. Ruoff
@nl
Rodney S. Ruoff
@sl
رادنی اس. روف
@azb
ロドニー・ルオフ
@ja
prefLabel
Rodney S. Ruoff
@ast
Rodney S. Ruoff
@ca
Rodney S. Ruoff
@de
Rodney S. Ruoff
@en
Rodney S. Ruoff
@es
Rodney S. Ruoff
@fr
Rodney S. Ruoff
@nl
Rodney S. Ruoff
@sl
رادنی اس. روف
@azb
ロドニー・ルオフ
@ja
P108
P214
P244
P106
P108
P21
P214
P244
P31
P569
1957-01-01T00:00:00Z
P734
P735
P7859
lccn-n94122609