P185
Directional control in thermally driven single-molecule nanocarsAtomic cobalt on nitrogen-doped graphene for hydrogen generation.Synthesis of anthropomorphic molecules: the NanoPutiansDirect covalent grafting of conjugated molecules onto Si, GaAs, and Pd surfaces from aryldiazonium saltsLongitudinal unzipping of carbon nanotubes to form graphene nanoribbonsGraphene nanoribbon compositesEn route to a motorized nanocarDetecting the Biopolymer Behavior of Graphene Nanoribbons in Aqueous SolutionBiocompatibility of reduced graphene oxide nanoscaffolds following acute spinal cord injury in ratsGraphene oxide. Origin of acidity, its instability in water, and a new dynamic structural model.Laser-induced porous graphene films from commercial polymers.Enhanced MRI relaxivity of aquated Gd3+ ions by carboxyphenylated water-dispersed graphene nanoribbons.Separation of single-walled carbon nanotubes on silica gel. Materials morphology and Raman excitation wavelength affect data interpretation.A study of the formation, purification and application as a SWNT growth catalyst of the nanocluster [HxPMo12O40[subset]H4Mo72Fe30(O2CMe)15O254(H2O)98].Molecular engineering of the polarity and interactions of molecular electronic switches.Accurately determining single molecule trajectories of molecular motion on surfaces.Functionalization of single-walled carbon nanotubes "on water".Improved synthesis of graphene oxide.Effective drug delivery, in vitro and in vivo, by carbon-based nanovectors noncovalently loaded with unmodified Paclitaxel.Pristine graphite oxide.Layer-by-layer removal of graphene for device patterning.Electronic structure control of single-walled carbon nanotube functionalization.Coal as an abundant source of graphene quantum dots.Single wall carbon nanotube amplification: en route to a type-specific growth mechanism.Mechanism of graphene oxide formation.Noncovalent functionalization of carbon nanovectors with an antibody enables targeted drug deliveryFlexible and stackable laser-induced graphene supercapacitors.Flexible Boron-Doped Laser-Induced Graphene Microsupercapacitors.Three-dimensional patterning of solid microstructures through laser reduction of colloidal graphene oxide in liquid-crystalline dispersions.In situ imaging of the conducting filament in a silicon oxide resistive switch.In Situ Formation of Metal Oxide Nanocrystals Embedded in Laser-Induced Graphene.Noncovalent assembly of targeted carbon nanovectors enables synergistic drug and radiation cancer therapy in vivo.High-Performance Pseudocapacitive Microsupercapacitors from Laser-Induced Graphene.The microRNA miR-22 inhibits the histone deacetylase HDAC4 to promote T(H)17 cell-dependent emphysemaNanoparticulate carbon black in cigarette smoke induces DNA cleavage and Th17-mediated emphysema.Antioxidant carbon particles improve cerebrovascular dysfunction following traumatic brain injury.Unimolecular Submersible Nanomachines. Synthesis, Actuation, and MonitoringLaser-Induced Graphene in Controlled Atmospheres: From Superhydrophilic to Superhydrophobic Surfaces.Laser-Induced Graphene Layers and Electrodes Prevents Microbial Fouling and Exerts Antimicrobial Action.Three-Dimensional Printed Graphene Foams.
P50
Q27108549-F5FBB997-89A4-4751-A922-8B68927475C8Q27320535-376F2DEE-9D4F-4CCB-9122-CE233E52F16FQ28182353-45B7EB13-3E82-46E5-8E3C-08100110E380Q28237509-4C83D4E6-98FF-4ED6-B990-CBA37680E8F7Q28241458-8681114E-B21A-420B-8286-D19A3BF24CDCQ28298482-2B046092-265C-46F9-9DFA-8536EEF98A37Q28305982-870042D3-10A7-4018-B4C8-5945DC9CC5FEQ28831062-6AEC0408-6A00-4FFE-83DC-6DC55FDC4048Q28831439-D8B4AA76-1895-46DD-9139-2EB48CF608ABQ30580277-E2C15F78-7ECD-40C0-837F-06B6C184500CQ30607734-42502D0C-A411-4ECF-8F03-5DA5B43FAD7EQ30750984-D793F466-56D8-4CFF-ACF8-FD09393B13DCQ30985466-90445B9B-8AC2-48CA-A277-0E5BBB6C1938Q31045153-822E69E3-5E6D-4AD1-8150-C9E67C35ABD0Q33228668-3533C32A-93F4-4863-BF15-FD28B93BF719Q33436955-3E9F32D3-299C-4FD4-B52F-EE791EE6901EQ33999805-2C23113D-BCA6-4BFB-AE00-118200AED9B2Q34023581-A6996C48-F04D-4ADD-99AB-C9E9C42336DCQ34111578-BEAC1C31-D58D-475B-974B-448452A778DDQ34125585-9E8831AD-0892-40AB-9E61-CEB8D6A185E7Q34169270-9228346A-AC6F-413E-88FA-260AB5B8E2D7Q34230022-974C3587-FCDD-49F0-8164-F9CF05BFA9CFQ34389961-D8E79EDD-8DEA-4487-A093-72E6D1632DE8Q34587540-8A64A99F-A4F0-4A4C-87A6-B5CADA49CF97Q35102699-066EFB71-396D-405B-B248-37598B9E33B7Q35177908-FC8BA4DB-C571-49BD-AD47-8979E1F29099Q35542151-CB28F851-32B4-462C-B8B5-0753BFC371BBQ35632579-70649D4C-8CD1-4F2D-B82E-3F17A978AEC7Q35637292-BE7C11E0-9E5E-43EE-8C90-10EE2DEDF67AQ35712775-94B7F309-E1F3-4039-9F5C-2CB76F6A4623Q35748815-E9BAFEE8-7FB0-4EC4-B38C-82A8D8120A04Q35856908-A36FF9B3-69C3-4838-9FFA-BED4BA4EF1EEQ35859691-7407930E-AC2E-4FEF-A2FC-B339AEB53312Q36134550-03CD6165-23FE-4AD4-AD32-1521056A23DDQ36182550-0278542D-997A-46D3-81FA-573AFF5BF4BBQ36279289-31E310D3-A141-4BB2-A8AC-1F29F1BB5FF1Q36364977-ACA9BDD4-5DE1-4BE1-BBDB-F0D251CE95A4Q36370025-CB33C5FF-6A09-499B-9DC6-52A69CF7D8C8Q36375399-6F8BC8E2-C21F-4E25-A529-8C43A8EA5316Q36400250-1B1853CB-B5B5-4651-8B3B-4AADB8F893A7
P50
description
Ameerika Ühendriikide keemik
@et
American chemist
@en
Amerikaans scheikundige
@nl
US-amerikanischer Chemiker
@de
Usana kemiisto
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amerikansk kemiker
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amerikansk kemist
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amerikansk kjemikar
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amerikansk kjemiker
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ceimiceoir Meiriceánach
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name
James Mitchell Tour
@de
James Tour
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James Tour
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James Tour
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James Tour
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James Tour
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James Tour
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James Tour
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James Tour
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James Tour
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type
label
James Mitchell Tour
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James Tour
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James Tour
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James Tour
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James Tour
@es
James Tour
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James Tour
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James Tour
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James Tour
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James Tour
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James M Tour
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James M Tour
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James M Tour
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James M Tour
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James Mitchell Tour
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prefLabel
James Mitchell Tour
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James Tour
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James Tour
@ca
James Tour
@en
James Tour
@es
James Tour
@fr
James Tour
@ga
James Tour
@it
James Tour
@nl
James Tour
@pt
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YwoecRMAAAAJ
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0000 0001 1662 748X