Water-mediated signal multiplication with Y-shaped carbon nanotubes
about
Binding of blood proteins to carbon nanotubes reduces cytotoxicityBio-mimicking of proline-rich motif applied to carbon nanotube reveals unexpected subtleties underlying nanoparticle functionalization.Overcoming the crystallization and designability issues in the ultrastable zirconium phosphonate framework system.Optimizing the design of nanostructures for improved thermal conduction within confined spaces.The role of basic residues in the adsorption of blood proteins onto the graphene surface.Y-junction carbon nanocoils: synthesis by chemical vapor deposition and formation mechanismSingle-file water in nanopores.Robust Denaturation of Villin Headpiece by MoS2 Nanosheet: Potential Molecular Origin of the NanotoxicityRotation motion of designed nano-turbine.Interactions between proteins and carbon-based nanoparticles: exploring the origin of nanotoxicity at the molecular level.Cytotoxicity of graphene: recent advances and future perspective.A controllable water signal transistor.Protein corona mitigates the cytotoxicity of graphene oxide by reducing its physical interaction with cell membrane.Capability of charge signal conversion and transmission by water chains confined inside Y-shaped carbon nanotubes.The ice-like water monolayer near the wall makes inner water shells diffuse faster inside a charged nanotube.Alcohol-induced drying of carbon nanotubes and its implications for alcohol/water separation: a molecular dynamics study.Accelerating water transport through a charged SWCNT: a molecular dynamics simulation.Effect of the computational domain size and shape on the self-diffusion coefficient in a Lennard-Jones liquid.Interface nanoparticle control of a nanometer water pump.From dimers to collective dipoles: Structure and dynamics of methanol/ethanol partition by narrow carbon nanotubes.Temperature dependence of the transport of single-file water molecules through a hydrophobic channel.Water transport through functionalized nanotubes with tunable hydrophobicity.Charge-signal multiplication mediated by urea wires inside Y-shaped carbon nanotubes.Effect of nanotube-length on the transport properties of single-file water molecules: transition from bidirectional to unidirectional.Reversible state transition in nanoconfined aqueous solutions.Modelling of the nanoscale.3D flexible water channel: stretchability of nanoscale water bridge.Graphene Oxide Nanosheets Retard Cellular Migration via Disruption of Actin Cytoskeleton.DNA translocation through single-layer boron nitride nanopores.The Solute-Exclusion Zone: A Promising Application for MirofluidicsAsymmetric self-diffusion with orientation-dependence of water molecule in finite timescaleImproved stability of water clusters (H2O)30–48: a Monte Carlo search coupled with DFT computationsWhat is the best density functional to describe water clusters: evaluation of widely used density functionals with various basis sets for (H2O) n (n = 1–10)
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Q28392671-E7D7B391-DEB0-4BE5-B10C-E17F4A33B721Q30009272-ACB2794D-4D2F-4D4F-9A60-49CF04BFC11CQ33766426-9AE63C8B-54B1-4875-A34A-284FE11423CAQ35537889-62914915-86FB-4BA5-957B-870D5490A45EQ35672774-9E446247-71AB-4C5C-94D5-85716D890DCDQ35716565-9BF76BDD-9077-4121-B5FC-405BE232DBA7Q36315966-D0928440-A79C-49DC-9483-A43CFBE5E6E3Q37014954-1FC14D25-C8F6-470F-8B75-9F10528C986EQ37733226-E9E2D58D-1A95-422B-8418-FD22ABF48F57Q38049565-BF01C01C-817A-4F77-AFD6-9E1598DAADF7Q38222637-8B34873E-C36A-4447-A0D0-233CB916FDD6Q38739156-FB4009AD-1B84-4391-8CCC-1EEDC4AAE155Q38840189-671EC019-D85A-4787-84D3-D165682AF475Q39489751-61F732BC-1FC9-4C72-A6E7-0E9C63FF1837Q45299062-6151356D-38E2-4BB1-B380-1F056127A90EQ45734766-204D8541-7FFB-4C57-ACB2-6DF050E0D2C3Q46156103-03FEB450-CC88-4BF5-B15F-56AABDA14676Q47411887-737B54BC-FF94-4091-A2EB-2B500C69082FQ47927878-39DC7DEA-5233-4662-A748-5CACBC705EADQ48520852-D5BD1B01-D8CF-47AD-BADC-A494A177C007Q48521438-1871E9FB-4030-488D-B6C8-5547A615DC5BQ48535647-38345219-A515-4A73-A1C0-0BCA3A1B16A1Q48539073-4C62F0FC-DA41-4B9B-9B25-21BDC83E3309Q48568445-A0DB7D06-DB2C-432E-AC77-E57F0AE170C3Q51107112-4BD9048F-18EC-4201-9580-2F04DE04C362Q51404996-4065EDAB-B623-4D98-833A-257DF7FAF908Q51468906-B7CBE022-A1B5-4792-98C0-0105A295C480Q52675962-98B78C67-AAA5-4129-8D9B-6D1E2F99B505Q53288619-A28E0AF5-7D6D-41F9-BC34-09D180786F0FQ56452037-0F5864AB-598E-4612-B531-CC5D038AD072Q58226012-3A06E7D5-931D-4EAE-8502-708B79FAC099Q58485297-80D108F5-8784-43DF-A84B-9A600D4319B4Q58485312-2D5F0FE9-82A6-4AC7-9F4A-F14396E172B6
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Water-mediated signal multiplication with Y-shaped carbon nanotubes
description
article científic
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article scientifique
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articolo scientifico
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artigo científico
@pt
bilimsel makale
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scientific article published on 08 October 2009
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vedecký článok
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vetenskaplig artikel
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videnskabelig artikel
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vědecký článek
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name
Water-mediated signal multiplication with Y-shaped carbon nanotubes
@en
Water-mediated signal multiplication with Y-shaped carbon nanotubes.
@nl
type
label
Water-mediated signal multiplication with Y-shaped carbon nanotubes
@en
Water-mediated signal multiplication with Y-shaped carbon nanotubes.
@nl
prefLabel
Water-mediated signal multiplication with Y-shaped carbon nanotubes
@en
Water-mediated signal multiplication with Y-shaped carbon nanotubes.
@nl
P2093
P2860
P356
P1476
Water-mediated signal multiplication with Y-shaped carbon nanotubes
@en
P2093
Haiping Fang
Rongzheng Wan
Ruhong Zhou
P2860
P304
18120-18124
P356
10.1073/PNAS.0902676106
P407
P577
2009-10-08T00:00:00Z