Evidence for charge transfer in doped carbon nanotube bundles from Raman scattering
about
Raman intensity of single-wall carbon nanotubesElectronic and transport properties of nanotubesOn the photophysics of butadiyne bridged pyrene-phenyl molecular conjugates: multiple emissive pathways through locally excited, intramolecular charge transfer and excimer states.Infrared multiphoton electron detachment spectroscopy of C76(2-).3D NiO hollow sphere/reduced graphene oxide composite for high-performance glucose biosensor.Stable and controlled amphoteric doping by encapsulation of organic molecules inside carbon nanotubes.Carbon nanotubes in nanocomposites and hybrids with hydroxyapatite for bone replacements.Metal-semiconductor transition like behavior of naphthalene-doped single wall carbon nanotube bundles.Intercalation-assisted longitudinal unzipping of carbon nanotubes for green and scalable synthesis of graphene nanoribbons.Rapid prototyping of carbon-based chemiresistive gas sensors on paper.Tuning the redox activity of encapsulated metal clusters via the metallic and semiconducting character of carbon nanotubes.Cu3P/RGO Nanocomposite as a New Anode for Lithium-Ion BatteriesChemistry in the nanospace of carbon nanotubes.Spectroelectrochemistry of carbon nanotubes.Strategy for carrier control in carbon nanotube transistors.Mechanochemistry of fullerenes and related materials.Raman spectroscopy on Mars: identification of geological and bio-geological signatures in Martian analogues using miniaturized Raman spectrometers.Highly water-soluble multi-walled carbon nanotubes amine-functionalized by supercritical water oxidation.Graphene versus Multi-Walled Carbon Nanotubes for Electrochemical Glucose Biosensing.Electron Density Modification of Single Wall Carbon Nanotubes (SWCNT) by Liquid-Phase Molecular Adsorption of Hexaiodobenzene.Non-covalent polymer wrapping of carbon nanotubes and the role of wrapped polymers as functional dispersants.Electronic and Optical Properties of Single Wall Carbon Nanotubes.Enlightening the ultrahigh electrical conductivities of doped double-wall carbon nanotube fibers by Raman spectroscopy and first-principles calculations.Significant enhancement of optical absorption through nano-structuring of copper based oxide semiconductors: possible future materials for solar energy applications.Coaxial nanocables of codoped double-walled carbon nanotubes.Anionic complexes of MWCNT with supergiant cyanobacterial polyanions.Electronic structures and three-dimensional effects of boron-doped carbon nanotubes.Pie-like electrode design for high-energy density lithium-sulfur batteries.Mechanistic insight into the catalytic oxidation of cyclohexane over carbon nanotubes: kinetic and in situ spectroscopic evidence.A selective voltammetric method for uric acid detection at beta-cyclodextrin modified electrode incorporating carbon nanotubes.Functionalization of carbon nanotubes using phenosafranin.Ion doping of graphene for high-efficiency heterojunction solar cells.Modeling zigzag CNT: dependence of structural and electronic properties on length, and application to encapsulation of HCN and C2H2.Superb Electrically Conductive Graphene Fibers via Doping Strategy.Electrically Activated Conductivity and White Light Emission of a Hydrocarbon Nanoring-Iodine Assembly.A one-pot-one-reactant synthesis of platinum compounds at the nanoscale.Versatile p-Type Chemical Doping to Achieve Ideal Flexible Graphene Electrodes.A hybrid of holey graphene and Mn3O4 and its oxygen reduction reaction performance.Ionic liquid for in situ Vis/NIR and Raman spectroelectrochemistry: Doping of carbon nanostructures.Noncovalent interactions between organometallic metallocene complexes and single-walled carbon nanotubes.
P2860
Q27348322-31969E18-2FFD-4A3E-B10B-21AF536230ECQ27349913-6811A7F0-18C8-4DA4-AE06-D4712B1912D4Q30885404-65524FB7-2DD5-449B-94B4-D4CBED2D671CQ33507649-A0F4A1AA-182E-45C3-A2CA-719635EA959DQ33899417-018A14E2-48FA-4A6B-B26B-055DC3758677Q34228374-793F6B33-BC1D-499E-82F1-F0285798AD00Q35110238-70265C57-D15E-4D91-B56D-2AE06232D8A8Q35480495-676C6162-B1EE-469E-A06A-5377EB48CD14Q36657217-2E12C73D-1278-47F8-AB10-A73232F10A03Q37143433-6535C98F-0EB4-490A-BE8D-63B1CA5F1C0DQ37173052-9FABACBC-4CC2-4F5F-AD32-BCFE1F34BF68Q37325278-C33CDC11-58A4-4075-AFEE-71E9957D1253Q37709289-A3F85022-64D2-492F-876B-900D1C0B9E19Q37827839-77A2E6AB-0BF7-4477-9D5A-C38394493BE3Q37873898-EB362F82-836C-4115-9986-913632398BA5Q38107104-931D0A89-EE1E-41CF-B124-D36861897E7EQ38264885-448422F4-0244-444D-A559-1D757EC6159AQ38446679-FFC251F1-CFB9-41B5-899D-43DCBD2C1539Q38624101-2B48444B-1139-4B79-8BA6-AF9133B5BF2FQ38624178-1EDCD61B-4DD7-4082-A008-1F6A08FAE939Q39017533-3A18C3D0-0342-4CCD-83C3-E576036A5091Q39061910-197E72FD-C85C-4966-9648-A95E7B204084Q39178676-B81F0753-EA8C-4C8B-9159-CEF3E66C3198Q39201970-7747A682-AABA-4047-9A2E-E0C39C696A51Q39921634-5A7E5258-920F-48FD-9C3E-FD66065A418AQ41612352-E3E1C160-99DB-4EAA-894F-06E32A506DC2Q41820815-3D028573-2A30-4D5E-9B5C-9C3AB3A5BA51Q42040969-2091741A-2CC1-425C-AACC-E3D39317F4B8Q43920216-0EDEBE56-1269-4D59-BCF5-BC691282538CQ44215567-FD5D92A8-E721-4F86-9512-BAE46BB2D63FQ44988438-09F12951-2B28-4999-B1D1-8B252D504D8EQ45378133-AAEC5F00-8AB1-4C1C-8E35-B47743F6C200Q46392692-E3C81D10-08B3-4525-B271-9C3355ACB3C9Q46523406-02A22BD2-B2EC-4536-B0FA-1D99F19E808CQ48060178-2FEC3F7E-6D09-457B-A79B-9E721F952EE9Q49836160-CB96CFC0-E3DB-4E47-A873-F4F229CDAC3EQ50229948-C945E350-9D3D-4A79-839A-418A1FB6ABCEQ50440105-B9374A33-5652-4951-A530-68E3BB8B0983Q50492457-2570EB11-C556-402F-869A-3894A0A95530Q50710718-C7A608E8-1C9F-4145-9539-A56BD85B13ED
P2860
Evidence for charge transfer in doped carbon nanotube bundles from Raman scattering
description
article publié dans la revue scientifique Nature
@fr
scientific article published in Nature
@en
wetenschappelijk artikel
@nl
наукова стаття, опублікована в Nature в липні 1997
@uk
name
Evidence for charge transfer in doped carbon nanotube bundles from Raman scattering
@en
Evidence for charge transfer in doped carbon nanotube bundles from Raman scattering
@nl
type
label
Evidence for charge transfer in doped carbon nanotube bundles from Raman scattering
@en
Evidence for charge transfer in doped carbon nanotube bundles from Raman scattering
@nl
prefLabel
Evidence for charge transfer in doped carbon nanotube bundles from Raman scattering
@en
Evidence for charge transfer in doped carbon nanotube bundles from Raman scattering
@nl
P2093
P2860
P356
P1433
P1476
Evidence for charge transfer in doped carbon nanotube bundles from Raman scattering
@en
P2093
P. C. Eklund
R. E. Smalley
Shunji Bandow
P2860
P2888
P304
P356
10.1038/40827
P407
P577
1997-07-01T00:00:00Z
P6179
1003534782