about
Amoeboid cells use protrusions for walking, gliding and swimmingEnvelope structure of Synechococcus sp. WH8113, a nonflagellated swimming cyanobacteriumArtificial Molecular MachinesOn the mysterious propulsion of SynechococcusGeometric tuning of self-propulsion for Janus catalytic particles.Swimming droplets driven by a surface wave.The motility of mollicutes.Myxobacteria gliding motility requires cytoskeleton rotation powered by proton motive force.Reverse engineering the euglenoid movement.Fidelity of adaptive phototaxisFinding the ciliary beating pattern with optimal efficiency.Low-Reynolds-number swimming at pycnoclines.Digital holographic microscopy reveals prey-induced changes in swimming behavior of predatory dinoflagellatesGreen Algae as Model Organisms for Biological Fluid DynamicsATP Consumption of Eukaryotic Flagella Measured at a Single-Cell LevelSquirmers with swirl: a model for Volvox swimming.Self-propulsion and interactions of catalytic particles in a chemically active medium.Ionic screening and dissociation are crucial for understanding chemical self-propulsion in polar solvents.Suspension biomechanics of swimming microbes.Calcium is required for swimming by the nonflagellated cyanobacterium Synechococcus strain WH8113.Phase separation and coexistence of hydrodynamically interacting microswimmers.Low-Reynolds-number swimmer utilizing surface traveling waves: analytical and experimental study.Can phoretic particles swim in two dimensions?Fluid transport by active elastic membranes.Simple swimmer at low Reynolds number: three linked spheres.Stochastic microswimming model for the average translational velocity of the ribosome.Shape-directed dynamics of active colloids powered by induced-charge electrophoresis.Buckling Instability Causes Inertial Thrust for Spherical Swimmers at All Scales.Swimming efficiency in a shear-thinning fluid.Stresslets Induced by Active Swimmers.Active Brownian motion of emulsion droplets: Coarsening dynamics at the interface and rotational diffusion.Dynamics of a microorganism in a sheared viscoelastic liquid.Microscale swimming: the molecular dynamics approach.Locomotion of a microorganism in weakly viscoelastic liquids.Brownian microhydrodynamics of active filaments.Three-sphere low-Reynolds-number swimmer with a passive elastic arm.Anisotropic particle in viscous shear flow: Navier slip, reciprocal symmetry, and Jeffery orbit.Swimming efficiency of spherical squirmers: beyond the Lighthill theory.Modeling microscopic swimmers at low Reynolds number.Pros and cons of swimming in a noisy environment.
P2860
Q21090971-F5D5AB7A-EC0E-4A40-9814-B627E4FB4BD1Q24797671-1027BFF4-6566-420A-8E7D-F6B706F7EDD0Q26783064-2DC5D7DD-A618-4B59-94C4-473A515582C6Q27303814-F583CBA6-8961-4DF7-82B3-17259EE99DA4Q30361222-8D6FF808-1AD3-40ED-86F1-E6E39B584CC2Q30417390-6093A0AC-5E12-42B4-BD4A-0EC44143DD2DQ30476426-80913466-13C2-4D19-926B-118AB0891C81Q30498174-FB8D9D61-C74F-4504-983F-44AD007CD7EEQ30528338-6313A6D7-F360-402F-9D9B-4F4D439CF21BQ33953429-E7E28702-6D1C-4582-A4B1-05A6535C3BF2Q35229315-56FD11E8-2822-47A3-99AA-5BD504FB45FDQ35844962-B4228521-813B-4962-81CC-AE8C3654C2DDQ36141543-E25279F6-42B7-4A10-AF48-0B945CB10E5FQ36292597-669F70A3-1234-4C6A-A8E5-4AEA5ABE83ABQ36426472-06668D29-6593-432C-B685-A69C2BCA98BDQ37349812-90FF9AE1-2D89-4182-ABF6-5580678022D8Q38717403-A2581019-8108-47FF-B9F6-9F63F1556B51Q38769073-A65A58E5-A3A2-40BF-8727-B2F2CA0C6F2CQ39614210-A41080FE-E2D5-41BB-94AE-78C9647FB075Q39845305-65C56519-35B9-436E-BF2D-37423F3F969FQ44838588-0AD4D6E1-8F40-4661-9801-9C97BC7AB68DQ45900756-7E60EB96-5538-464F-BF3B-42B4E147069DQ46432934-952148F9-7ED5-4F71-B33E-3F2C5B6CA952Q46725895-78AEA7C7-59DB-4861-813E-D13667139E2CQ47222003-3ED716EB-5BD5-4ADF-B3EA-09B0D6BA288AQ47780926-CAE9058A-A1A7-4312-BC2D-3DF4AF92098AQ48044458-50EDD127-B13D-4834-BA64-FEDD7E42CB3BQ49495192-886C4574-D1BD-4123-95E3-B4A440192F5DQ49960385-B9076725-FD4F-4CE5-B668-8F13AE41AB6BQ50571321-AAC2F719-5B9C-402A-A6B3-961667C974B2Q50591302-88AE4BA0-4066-4B7D-B06E-A15ACB5FB14BQ50610306-E1FD9100-1A27-4912-B679-4818C123857DQ50656815-33DAA661-8B7A-48BF-A13A-F2BE7A4C8241Q50758717-CB117811-3C45-4746-8D76-B2DD7A41E632Q50786668-02B16B28-DDDE-4EFB-AFDC-70F206CEE85BQ50911661-BF6B3A8D-9613-4E77-B248-392385ED1CB7Q50932122-209663A1-B374-43E5-A2D2-DBF3B9B9D436Q51056714-FB88A474-9BFB-4C74-8AA0-E5BE5F87A75DQ51063069-6CC0DB6F-66EC-48F6-A678-4620611F264BQ51094279-1CF6D4FD-6D14-45FE-81BD-1B54695252DF
P2860
description
1996 nî lūn-bûn
@nan
1996 թուականի Նոյեմբերին հրատարակուած գիտական յօդուած
@hyw
1996 թվականի նոյեմբերին հրատարակված գիտական հոդված
@hy
1996年の論文
@ja
1996年論文
@yue
1996年論文
@zh-hant
1996年論文
@zh-hk
1996年論文
@zh-mo
1996年論文
@zh-tw
1996年论文
@wuu
name
Propulsion of Microorganisms by Surface Distortions
@ast
Propulsion of Microorganisms by Surface Distortions
@en
Propulsion of Microorganisms by Surface Distortions
@nl
type
label
Propulsion of Microorganisms by Surface Distortions
@ast
Propulsion of Microorganisms by Surface Distortions
@en
Propulsion of Microorganisms by Surface Distortions
@nl
prefLabel
Propulsion of Microorganisms by Surface Distortions
@ast
Propulsion of Microorganisms by Surface Distortions
@en
Propulsion of Microorganisms by Surface Distortions
@nl
P2860
P3181
P1476
Propulsion of Microorganisms by Surface Distortions
@en
P2093
Aravinthan D. T. Samuel
Howard A. Stone
P2860
P304
P3181
P356
10.1103/PHYSREVLETT.77.4102
P407
P577
1996-11-04T00:00:00Z