Electrokinetic transport in nanochannels. 2. Experiments.
about
Fundamental studies of nanofluidics: nanopores, nanochannels, and nanopipetsCharacterizing dispersion in microfluidic channels.Impact of leakage current and electrolysis on FET flow control and pH changes in nanofluidic channelsNanocapillaries for open tubular chromatographic separations of proteins in femtoliter to picoliter samples.Experimentally and theoretically observed native pH shifts in a nanochannel array.Single-nanopore investigations with ion conductance microscopy.Electroosmotic flow in nanofluidic channels.Electrophoresis in nanochannels: brief review and speculationThe effect of translocating cylindrical particles on the ionic current through a nanoporeElectronic drop sensing in microfluidic devices: automated operation of a nanoliter viscometer.Nanotechnology for membranes, filters and sieves. A series of mini-reviews covering new trends in fundamental and applied research, and potential applications of miniaturised technologies.Flexible fabrication and applications of polymer nanochannels and nanoslitsOn the propagation of concentration polarization from microchannel-nanochannel interfaces. Part II: Numerical and experimental study.On the propagation of concentration polarization from microchannel-nanochannel interfaces. Part I: Analytical model and characteristic analysis.Chromatographic separations in a nanocapillary under pressure-driven conditionsSilicon micro- and nanofabrication for medicineTheoretical models for electrochemical impedance spectroscopy and local ζ-potential of unfolded proteins in nanopores.Bare nanocapillary for DNA separation and genotyping analysis in gel-free solutions without application of external electric field.AC Electroosmotic Pumping in Nanofluidic Funnels.Nanofluidics in chemical analysis.Field effect nanofluidics.Electroosmotic flow in single PDMS nanochannels.Interrogating Surface Functional Group Heterogeneity of Activated Thermoplastics Using Super-Resolution Fluorescence MicroscopyElectrophoretic Separation of Single Particles Using Nanoscale Thermoplastic Columns.Size-dependent trajectories of DNA macromolecules due to insulative dielectrophoresis in submicrometer-deep fluidic channels.Hydronium-dominated ion transport in carbon-dioxide-saturated electrolytes at low salt concentrations in nanochannels.Molecular dynamics simulation of electro-osmotic flows in rough wall nanochannels.Analysis of electrolyte transport through charged nanopores.Separation behavior of short single- and double-stranded DNA in 1 micron and 100 nm glass channels.Electrocavitation in nanofluidics: unique phenomenon and fundamental platform.Where there is a valley, there is a peak: study of ion size and image effects on nanoelectroosmotic pumping.Modeling the effect of sonication parameters on size and dispersion temperature of solid lipid nanoparticles (SLNs) by response surface methodology (RSM).Electroviscous resistance of nanofluidic bends.Limits of miniaturization: assessing ITP performance in sub-micron and nanochannels.Highly efficient and ultra-small volume separation by pressure-driven liquid chromatography in extended nanochannels.A flux monitoring method for easy and accurate flow rate measurement in pressure-driven flows.A low-voltage electrokinetic nanochannel drug delivery system.Selective trapping and concentration of nanoparticles and viruses in dual-height nanofluidic channels.Electrokinetic transport through nanochannels.Molecular Dynamics Simulation of Composite Nanochannels as Nanopumps Driven by Symmetric Temperature Gradients
P2860
Q26825104-5210AA0B-8F13-48E8-9AC9-6DBC6834A667Q30492965-ADEB6EC8-1C70-4EEE-9321-F7A8D92F3B23Q33449436-AB0AF649-B8DC-4DDB-9DD3-56EF03138778Q33491706-68ABE2B2-5B6D-48F1-8F39-3C6112E049E6Q34013190-98349E8C-65B8-4741-8417-4C6C1E3B3A51Q34020738-C3083DAF-045B-426A-9EAE-67601A289FD5Q34548062-78767421-7872-4283-8160-E5B98E8FD36EQ35205612-5A4009D1-E414-4AD4-A5D7-43B3EE6F78F0Q35613626-0C0B72AB-2BCA-4CBD-ADED-EEDE551B0237Q36004686-E688AC34-5A9F-46E5-B8A7-669449854D8DQ36350247-6C024D6A-87DE-4EC0-972F-9B71936BA29DQ36638719-2761CDF5-256B-4872-A780-AD1F3DA64DD2Q36752552-ED6EAD86-EDC8-48B9-8E04-73DA8216F87BQ36752574-EBFDDCC3-3944-4CC3-BCFF-CE6226E86790Q36973081-C88F152C-8B2A-4C11-A3A5-49ED3665FE1BQ37184228-AAD39A67-F7A6-4D26-B5ED-6C03EC377CF4Q37203271-68892888-D09F-459A-A6C8-C672C2798D35Q37252266-AA1C798A-A0C5-4858-8D3C-FF60291E14B8Q37359385-EE48C7AF-B5AC-4730-94BE-E9A2B6BB0332Q37697545-C02BF353-9635-4D56-91B1-BC5F1DCC61E1Q38813998-4473F54A-0018-4D4F-9EF7-3874EAF04156Q38858858-04580A12-87F1-4BAB-80F4-D9CBA703E3AFQ39959306-EA610FFD-6C36-4A0E-AC55-EE3C78BED584Q41379685-AA81CD8F-2015-4217-B9A6-014CA4678485Q41894257-91F65B49-9E56-4C1F-A54C-F1531938A834Q43529044-399798F6-5ABA-458D-92A2-DB5670A0593BQ45934104-E731077E-07EB-439B-A2EC-B2B770614B88Q46115856-7AF5E58D-0A05-4BBA-9A01-4E177C9DB8AFQ46393636-2544B4B6-F7F1-43EE-A568-6D6FB327DF9AQ46707687-EAAFD7DF-F568-44D1-80A8-1F5E66632856Q47234625-162B11AE-22E0-4393-8DB4-0F84F7B21310Q47241111-FE80C21C-A826-48C9-A385-A2062B241ABAQ51505522-9644C99B-50E0-4062-9D77-B4C2961546E8Q51539376-DA93B02A-BECE-4BEF-8924-95F3569A8FAEQ51541857-2FD7310F-FF5E-4313-A5A3-C02C36FA1068Q51542919-23C7111E-D793-406D-A790-06430180B5EEQ51548127-1121945C-CBD4-4FB6-AF21-618B0DBD70CAQ51560996-DD139DDC-26EC-431B-9CF5-A1A04299AAFCQ51572769-46F5264A-3E37-44AE-9F35-E6879EE6D260Q58778270-56B07375-BFCA-4ABE-8B66-C35F254DF0CB
P2860
Electrokinetic transport in nanochannels. 2. Experiments.
description
2005 nî lūn-bûn
@nan
2005年の論文
@ja
2005年学术文章
@wuu
2005年学术文章
@zh-cn
2005年学术文章
@zh-hans
2005年学术文章
@zh-my
2005年学术文章
@zh-sg
2005年學術文章
@yue
2005年學術文章
@zh
2005年學術文章
@zh-hant
name
Electrokinetic transport in nanochannels. 2. Experiments.
@en
Electrokinetic transport in nanochannels. 2. Experiments.
@nl
type
label
Electrokinetic transport in nanochannels. 2. Experiments.
@en
Electrokinetic transport in nanochannels. 2. Experiments.
@nl
prefLabel
Electrokinetic transport in nanochannels. 2. Experiments.
@en
Electrokinetic transport in nanochannels. 2. Experiments.
@nl
P356
P1433
P1476
Electrokinetic transport in nanochannels. 2. Experiments.
@en
P2093
Juan G Santiago
Sumita Pennathur
P304
P356
10.1021/AC0508346
P407
P577
2005-11-01T00:00:00Z