about
Cytoplasmic electric fields and electroosmosis: possible solution for the paradoxes of the intracellular transport of biomoleculesCapillarity-based switchable adhesion.High-performance, low-voltage electroosmotic pumps with molecularly thin silicon nanomembranesElectrofilament deposition and off-column detection of analytes separated by capillary electrophoresis.The electroosmotic droplet switch: countering capillarity with electrokineticsRecent progress in capillary electrochromatography.Capillary electrophoresis-a high performance analytical separation technique.Three-dimensional integrated microfluidic architectures enabled through electrically switchable nanocapillary array membranesStreaming current magnetic fields in a charged nanopore.Versatile ultrathin nanoporous silicon nitride membranes.Nanofluidics in chemical analysis.Theory, fabrication and applications of microfluidic and nanofluidic biosensors.The apparent hydrodynamic slip of polymer solutions and its implications in electrokinetics.Multiscale Multiphysics and Multidomain Models I: Basic Theory.In-vitro nanodiagnostic platform through nanoparticles and DNA-RNA nanotechnology.Field effect nanofluidics.Insignificance of active flow for neural diffusion weighted imaging: A negative result.Electroosmotic flow in single PDMS nanochannels.Electrohydrodynamics within the electrical double layer in the presence of finite temperature gradients.Electro-osmotic flow enhancement in carbon nanotube membranes.Thin film electro-osmotic pumps for biomicrofluidic applications.Electroosmotic flow in vapor deposited silicon dioxide and nitride microchannels.Enhancement of charged macromolecule capture by nanopores in a salt gradient.Enhancement of electroosmotic flow in capillary electrochromatography.Effect of electrical double layer on electric conductivity and pressure drop in a pressure-driven microchannel flow.Label free detection of nucleic acids by modulating nanochannel surfaces.Regimes of streaming potential in cylindrical nano-pores in presence of finite sized ions and charge induced thickening: an analytical approach.Numerical homogenization of electrokinetic equations in porous media using lattice-Boltzmann simulations.Molecular dynamics simulation of electro-osmotic flows in rough wall nanochannels.Translational and rotational near-wall diffusion of spherical colloids studied by evanescent wave scattering.Induced charge electroosmosis micropumps using arrays of Janus micropillars.Caterpillar locomotion-inspired valveless pneumatic micropump using a single teardrop-shaped elastomeric membrane.Method to determine the effective ζ potential in a microchannel with an embedded gate electrode.Filling of charged cylindrical capillaries.From Ion Current to Electroosmotic Flow Rectification in Asymmetric Nanopore Membranes.Optimal design of graphene nanopores for seawater desalination.Review: Electric field driven pumping in microfluidic device.Numerical study of enhanced mixing in pressure-driven flows in microchannels using a spatially periodic electric field.Streaming-field-induced convective transport and its influence on the electroviscous effects in narrow fluidic confinement beyond the Debye-Hückel limit.Challenges in realizing a self-contained hydraulically-driven contractile fiber actuator.
P2860
Q27027573-6CA069BE-883C-49A9-94DA-694FD8E87480Q30493736-96502EFB-E28C-4C7A-BCD9-0EC78E26C126Q30557405-B02D1059-08BA-4BB8-B3A1-02F4854FFF9FQ30873247-68B2118C-87FA-44CD-AC6F-FD59B45BBA08Q33922942-3A1BA47A-02BF-4A82-A5C4-8B74D9A08E71Q34147190-8A2C990B-2BA5-443A-9514-ECF63FA7C0BCQ35184588-21C21A57-4A3C-479E-8325-89EE6279B68CQ37280211-FD8AC9F9-723C-4B8B-8865-D5E8B5E9DC3FQ37408402-EE474E49-B0E2-4677-B8F8-26D3A955E556Q37482183-B90FFDC1-6106-4373-83FB-6034C4D358E6Q37697545-7F7A14D2-2239-4A7C-921F-30C3947D2E38Q38003136-0F3AC7FC-ECA1-4F86-9820-04D2AB1A8A4FQ38068785-F18988B0-8EBD-4F5F-8490-28AE34AA663BQ38266440-80BD39D1-09BD-4347-BE9A-489B425741BAQ38374130-B2E30790-5C38-4D23-B681-04A87E4C759DQ38813998-FD1C14B0-0A1C-4D05-A6BD-268CC2A44E8FQ38832601-84C27B5C-49C8-4917-8483-FF9A396BCA0DQ38858858-3E918578-F50F-4A38-BAE9-0B75ABF61169Q39296779-EBDEBEAC-2F2F-401B-9407-8F7A81DD22E8Q40163114-DC8604F7-5D9D-4180-8917-0F9EAAB0F5C2Q40256228-04D12571-DB85-4849-9EC1-3E28B8C648C6Q41958862-889C81E8-D6DE-4173-92E5-CA61211FE684Q42540104-FC0BB8FB-540B-4A74-94F5-BA61D81D65AFQ42663472-4B084576-4D1B-45F8-BA44-616EFB85E98EQ42730775-5F1B4B29-43EA-4ABE-962D-26541B879829Q43673508-BD01C2DE-24D7-4211-996A-B39C14874ACCQ44325568-D700F83D-BC16-4190-9D78-EF488BD8F569Q45224763-202E3810-F137-491F-BFF5-0690994AAE27Q45934104-CE7E89E2-7E54-46B2-BE5C-D1CA0D503D45Q45971951-FAB7A101-79C6-4F2A-B8C0-74205F342449Q46036923-1BB47A9A-4E11-4F80-82EF-F3D986CA0F2DQ46231042-74CC01F2-3802-4340-AE86-7B26623C0F8DQ46241960-A1966112-D6B2-4D80-8887-49D37169CBE8Q46817348-9A5EB54E-E367-4FDD-AC01-7C9F86C76384Q47096831-BD32CEEC-6131-4DA3-BEF6-81A1380634DAQ47196803-E7D90898-C83C-4202-B303-FD52B4DDF8F1Q47356046-7C403461-C923-4815-8E2B-AF3CAE32E25EQ47560636-CF2EE4A5-D525-40F5-9A88-084ED5CD15D3Q47669259-DA753627-977A-482B-B06B-BB9CBE788C71Q48062309-80636AAC-A8F4-4712-B6D0-FA67DC3C1A29
P2860
description
1965 nî lūn-bûn
@nan
1965 թուականի Նոյեմբերին հրատարակուած գիտական յօդուած
@hyw
1965 թվականի նոյեմբերին հրատարակված գիտական հոդված
@hy
1965年の論文
@ja
1965年論文
@yue
1965年論文
@zh-hant
1965年論文
@zh-hk
1965年論文
@zh-mo
1965年論文
@zh-tw
1965年论文
@wuu
name
Electrokinetic Flow in a Narrow Cylindrical Capillary
@ast
Electrokinetic Flow in a Narrow Cylindrical Capillary
@en
type
label
Electrokinetic Flow in a Narrow Cylindrical Capillary
@ast
Electrokinetic Flow in a Narrow Cylindrical Capillary
@en
prefLabel
Electrokinetic Flow in a Narrow Cylindrical Capillary
@ast
Electrokinetic Flow in a Narrow Cylindrical Capillary
@en
P3181
P356
P1476
Electrokinetic Flow in a Narrow Cylindrical Capillary
@en
P2093
C. L. Rice
R. Whitehead
P304
P3181
P356
10.1021/J100895A062
P577
1965-11-01T00:00:00Z