about
Chemotaxis of bio-hybrid multiple bacteria-driven microswimmersActive micromachines: Microfluidics powered by mesoscale turbulence.Light-induced self-assembly of active rectification devices.A model of filamentous cyanobacteria leading to reticulate pattern formationActive Brownian particles and run-and-tumble particles separate inside a maze.Catalytically powered dynamic assembly of rod-shaped nanomotors and passive tracer particles.Swimming bacteria power microscopic gearsBacterial ratchet motors.pH-Taxis of Biohybrid MicrosystemsA bead-spring model for running and tumbling of flagellated swimmers: detailed predictions compared to experimental data for E. coli.Biomimetic antimicrobial cloak by graphene-oxide agar hydrogel.Targeted delivery of colloids by swimming bacteriaArrested phase separation in reproducing bacteria creates a generic route to pattern formation.Chemotaxis when bacteria remember: drift versus diffusionMicromotors with asymmetric shape that efficiently convert light into work by thermocapillary effects.Phase separation and rotor self-assembly in active particle suspensionsActive dynamics of colloidal particles in time-varying laser speckle patterns.Green Algae as Model Organisms for Biological Fluid DynamicsRatchet transport powered by chiral active particlesShape and Displacement Fluctuations in Soft Vesicles Filled by Active Particles.Bacterial microsystems and microrobots.Directional transport of colloids inside a bath of self-propelling walkers.Development of a sperm-flagella driven micro-bio-robot.Suspension biomechanics of swimming microbes.Propulsion and Chemotaxis in Bacteria-Driven MicroswimmersRectification of self-propelled particles by symmetric barriers.Dynamics and separation of circularly moving particles in asymmetrically patterned arrays.Analytical modeling and experimental characterization of chemotaxis in Serratia marcescens.Microorganism billiards in closed plane curves.Rotational Diffusion of Soft Vesicles Filled by Chiral Active Particles.Memory-less response and violation of the fluctuation-dissipation theorem in colloids suspended in an active bath.Generalized Archimedes' principle in active fluids.Experimental investigation of mesoscopic heterogeneous motion of laser-activated self-propelling Janus particles in suspension.Activity-assisted self-assembly of colloidal particles.Thermal gas rectification using a sawtooth channel.Spontaneous symmetry breaking induced unidirectional rotation of a chain-grafted colloidal particle in the active bath.Entropy Production and Fluctuation Theorems for Active Matter.Elasticity-based polymer sorting in active fluids: a Brownian dynamics study.Transport of alignment active particles in funnel structures.Influence of swimming strategy on microorganism separation by asymmetric obstacles.
P2860
Q27314926-916E75D9-EDBE-465E-BC01-D9B7708BB078Q27334213-7A378C00-F227-4655-B181-995B6ADBFF4FQ27334240-D85746F0-E95C-4FF0-984A-3C18BF1FBF13Q28654462-D031DA3E-1327-4764-B498-0B9CEC96F571Q28820753-6FD59E65-32F1-4E0A-8F15-735BA28A1B6CQ30439492-7160E641-07BA-4F6C-A165-FBB40BDE27F5Q30493225-B87B5377-A81E-4807-9EAD-28D4C5AB6FBEQ30495578-7C4AD355-A8C8-4FEB-807D-B240DB430EC4Q30654334-7F1AA583-4C9F-48DE-9C4D-2563183F25BBQ30884536-4D300C28-D69A-47B6-9A23-A89EF781AA99Q33685059-028A06F6-4269-4F04-8188-BBD9D8B9EFCAQ33957059-E2191BB0-4C6B-4608-98CD-23082451A160Q33978100-A1155A9A-DDA3-4E21-91E1-D367C2926FC8Q35586850-65F9E1AD-2B3A-4E3B-9B0B-3B51B0DE7608Q35721800-90AF7B38-6615-493A-8C9A-AFA4C3F173E2Q35837096-7D89A3ED-5269-4916-B6E3-E0A160844484Q36045988-0EBAF35F-F31C-4588-B739-D84AF8134E97Q36292597-280D3260-ED2A-4837-A9EE-C299AA372597Q36500661-C2FA44C3-6824-4691-A62F-0603EEA2B8D3Q37291295-3B54D2E7-2DE4-46F5-B1AA-55BE1967C683Q38041950-542FA46A-53C7-41CF-B2EE-3C90727F3713Q38809517-20AC264D-A694-465B-8301-77891C390B27Q39357248-70A81379-95F0-4EB8-A382-B58937A7BFB6Q39614210-46FEAF41-82F3-4543-8B17-1269B47313DBQ41710995-5FA61AF1-E88E-4BBD-9893-5651CC119340Q43724605-66C73781-54E0-4860-80C4-7D6087A55678Q44193344-944505DF-A48B-4826-A769-61C953123FFAQ44517247-A0F20353-6098-487B-AEE9-D47BDB42A981Q46446378-C774F4DC-8D79-48F4-9CD5-CF633ED8B1F7Q47104083-7E72E445-9ACF-45EF-B02F-176584897E64Q47110068-8A86883D-595E-4FBF-ABF2-0965DD85D6DCQ48503247-581BEDDD-11DD-427B-BBD6-2103BD39FA99Q48506756-CE467B83-E770-4047-B488-4DF4C9F52A66Q49047514-627DAB9C-A2FE-48EF-A143-B4F12B026B27Q49962080-B0020868-E3B0-46E1-A4B0-5B1D5B2511E1Q50072982-BC4549DC-F7ED-4FDF-94AC-C12EFBBFF4EDQ50178391-A3D6BB38-535C-4BA2-9BFD-31BCBD9B82CDQ50545538-11D6563D-E663-4668-9305-7F9E9383BCD0Q50868736-AECABA5F-2E7E-4881-A12B-4B31EC7DEF2FQ50896347-DB81BF86-9E77-43BB-931E-66A0CB0F1C26
P2860
description
2009 nî lūn-bûn
@nan
2009 թուականի Յունուարին հրատարակուած գիտական յօդուած
@hyw
2009 թվականի հունվարին հրատարակված գիտական հոդված
@hy
2009年の論文
@ja
2009年論文
@yue
2009年論文
@zh-hant
2009年論文
@zh-hk
2009年論文
@zh-mo
2009年論文
@zh-tw
2009年论文
@wuu
name
Self-Starting Micromotors in a Bacterial Bath
@ast
Self-Starting Micromotors in a Bacterial Bath
@en
Self-Starting Micromotors in a Bacterial Bath
@nl
type
label
Self-Starting Micromotors in a Bacterial Bath
@ast
Self-Starting Micromotors in a Bacterial Bath
@en
Self-Starting Micromotors in a Bacterial Bath
@nl
prefLabel
Self-Starting Micromotors in a Bacterial Bath
@ast
Self-Starting Micromotors in a Bacterial Bath
@en
Self-Starting Micromotors in a Bacterial Bath
@nl
P2860
P50
P3181
P1476
Self-starting micromotors in a bacterial bath
@en
P2093
Luca Angelani
P2860
P304
P3181
P356
10.1103/PHYSREVLETT.102.048104
P407
P577
2009-01-30T00:00:00Z