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Single-particle electrophoresis in nanochannels.Switchable imbibition in nanoporous gold.Glass etching to bridge micro- and nanofluidics.Electroosmotic flow in nanofluidic channels.Surface charge, electroosmotic flow and DNA extension in chemically modified thermoplastic nanoslits and nanochannels.Fabrication of polydimethylsiloxane (PDMS) nanofluidic chips with controllable channel size and spacing.Modeling Elastic Pore Sensors for Quantitative Single Particle Sizing.Flexible fabrication and applications of polymer nanochannels and nanoslitsElectrokinetically-driven transport of DNA through focused ion beam milled nanofluidic channels.Resistive Pulse Analysis of Microgel Deformation During Nanopore TranslocationTheoretical models for electrochemical impedance spectroscopy and local ζ-potential of unfolded proteins in nanopores.AC Electroosmotic Pumping in Nanofluidic Funnels.Theory, fabrication and applications of microfluidic and nanofluidic biosensors.Fabrication of nanofluidic biochips with nanochannels for applications in DNA analysis.Block copolymer-derived monolithic polymer films and membranes comprising self-organized cylindrical nanopores for chemical sensing and separations.Nanofluidic crystals: nanofluidics in a close-packed nanoparticle array.Multiscale modeling of a rectifying bipolar nanopore: explicit-water versus implicit-water simulations.Thermoplastic nanofluidic devices for biomedical applications.Field effect nanofluidics.Multiscale modeling of a rectifying bipolar nanopore: Comparing Poisson-Nernst-Planck to Monte Carlo.Electroosmotic flow in single PDMS nanochannels.Interrogating Surface Functional Group Heterogeneity of Activated Thermoplastics Using Super-Resolution Fluorescence MicroscopyIon selective redox cycling in zero-dimensional nanopore electrode arrays at low ionic strength.Simulation of a model nanopore sensor: Ion competition underlies device behavior.Nanofluidics: A New Arena for Materials Science.Experimental verification of simultaneous desalting and molecular preconcentration by ion concentration polarization.3D Porous Hydrogel/Conducting Polymer Heterogeneous Membranes with Electro-/pH-Modulated Ionic Rectification.An Integrated Glass Nanofluidic Device Enabling In-situ Electrokinetic Probing of Water Confined in a Single Nanochannel under Pressure-Driven Flow Conditions.Site-specific nanopatterning of functional metallic and molecular arbitrary features in nanofluidic channels.A novel fluidic control method for nanofluidics by solvent-solvent interaction in a hybrid chip.From symmetric to asymmetric design of bio-inspired smart single nanochannels.Electro-osmotic flow through nanopores in thin and ultrathin membranes.Hydraulic transport across hydrophilic and hydrophobic nanopores: Flow experiments with water and n-hexane.Permselective 2D-polymer-based membrane tuneable by host-guest chemistry.On-demand in situ generation of oxygen in a nanofluidic embedded planar microband electrochemical reactor
P2860
Q30397780-7D91371C-A10C-46DA-A075-C4DED31AF3DDQ33915078-D006C388-E849-4361-8081-5CC06C3A7A14Q34070341-03E9B9B1-7751-4188-AF8E-9306ADB59F1EQ34548062-497A43A7-E7D1-431D-B9D8-31656825E7F7Q34794654-DEDE9EF4-E4F9-4F9F-A1A0-B8C61276E0E8Q36107531-C3B95289-5B5E-47F4-8C51-C59D3DD16570Q36196920-6712798F-E6E3-4245-811D-C06459035495Q36638719-06F9A09E-E936-4498-A306-871772DCDE9FQ36669236-65C2EA21-A202-4B0C-983C-620FFB99C9E8Q37036599-AAB2FEF1-EACB-4730-A495-C3F7C699D826Q37203271-86F92A7C-5CF9-4265-A0EC-0448DDDDD7DEQ37359385-F974443B-79E0-4453-83CF-E0209CF20329Q38003136-A6A0BC46-FBEB-4B6C-9DA8-2BF7D67EFCB3Q38025065-FF79880C-F25F-4413-8000-06CFF0B2B7C7Q38218581-4012096D-18E6-48F8-B99D-12C74B9A6CCEQ38650437-E6F24DA5-79CA-4BC7-8731-57FBB8BB9D11Q38705116-5E82B12D-BC5F-48B6-8128-9212458B0EB6Q38778799-12A753FF-D0F4-4060-95E0-CAA0926F0593Q38813998-7F8768BC-2D92-4B6E-AE71-67DEF4BEB3DBQ38847964-45C3FCDE-68CE-4F59-B022-FDD6E567F7D8Q38858858-C40D5E2C-E303-4D67-B22F-D89A6ADF474FQ39959306-5EF09832-DEF4-4D2A-9918-6159B4F1F883Q46386920-BD7E851F-2854-4F1F-9554-9CB7D42066F0Q47209387-702DB408-07DD-416C-B75F-78B33197A752Q47389122-25FA5634-F09D-4075-BDF2-819B86798668Q47578241-B507269B-D186-49C3-BDD0-AF11BF3736EEQ47653288-DB7A5240-28FB-4D37-872D-30B75B142104Q51479072-48235BB1-FF63-4220-B6ED-21066D31BF9AQ51497195-DC927F67-6525-4D9B-84B5-57E908CC8DCAQ51501869-E4B1137D-A718-4F04-8019-2C97DE93EA12Q51783096-C004CC87-34FF-4690-89E2-7D91114DE9FCQ51840656-7EFF9B7E-D81C-4000-92AA-160272B43A1DQ52856634-6FA05FB7-C019-4543-8F7D-5BFABE0B1677Q52998573-BB2E1871-4463-47E3-9D54-B34A9D52E02DQ57498796-5D77641D-9538-4CE7-8C79-8A0F9FF137D6
P2860
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on 23 October 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Nanofluidics in chemical analysis.
@en
Nanofluidics in chemical analysis.
@nl
type
label
Nanofluidics in chemical analysis.
@en
Nanofluidics in chemical analysis.
@nl
prefLabel
Nanofluidics in chemical analysis.
@en
Nanofluidics in chemical analysis.
@nl
P2093
P2860
P356
P1476
Nanofluidics in chemical analysis.
@en
P2093
Aigars Piruska
Jonathan V Sweedler
Maojun Gong
Paul W Bohn
P2860
P304
P356
10.1039/B900409M
P577
2009-10-23T00:00:00Z