about
Anomalous segregation dynamics of self-propelled particles.Mechanism for Collective Cell Alignment in Myxococcus xanthus BacteriaModeling filamentous cyanobacteria reveals the advantages of long and fast trichomes for optimizing light exposureCollective motion of spherical bacteriaPattern-formation mechanisms in motility mutants of Myxococcus xanthusPeriodic reversals in Paenibacillus dendritiformis swarming.Collective cell streams in epithelial monolayers depend on cell adhesionOn the duality between interaction responses and mutual positions in flocking and schooling.Collisions of deformable cells lead to collective migration.Symmetry-breaking phase transitions in highly concentrated semenSocial interactions in myxobacterial swarming.Dynamics of bacterial swarming.Keeping speed and distance for aligned motion.Shape control and compartmentalization in active colloidal cells.Continuum modeling of clustering of myxobacteria.Hysteresis, reentrance, and glassy dynamics in systems of self-propelled rods.Run-and-pause dynamics of cytoskeletal motor proteins.Dynamics of Snake-like Swarming Behavior of Vibrio alginolyticusSurface roughness stabilizes the clustering of self-propelled triangles.Generalized Swift-Hohenberg models for dense active suspensions.Determining the impact of cell mixing on signaling during development.Hydrodynamic length-scale selection in microswimmer suspensions.Anomalous Fluctuations in the Orientation and Velocity of Swarming Bacteria.Extracting cellular automaton rules from physical Langevin equation models for single and collective cell migration.Emergent pattern formation in an interstitial biofilm.Swarming and pattern formation due to selective attraction and repulsion.Phase separation and emergent structures in an active nematic fluid.Collective migration under hydrodynamic interactions: a computational approach.Cell flexibility affects the alignment of model myxobacteria.Computational design of chemically propelled catalytic nanorotors.Hydrodynamic interactions in dense active suspensions: From polar order to dynamical clusters.Simulating the hydrodynamics of self-propelled colloidal clusters using Stokesian dynamics.Controlling active self-assembly through broken particle-shape symmetry.Group-size distribution of skeins of wild geese.Helical paths, gravitaxis, and separation phenomena for mass-anisotropic self-propelling colloids: Experiment versus theory.Reentrant phase behavior in active colloids with attraction.Role of tumbling in bacterial swarming.Large-scale vortex lattice emerging from collectively moving microtubules.Multiscale Modulation of Nanocrystalline Cellulose Hydrogel via Nanocarbon Hybridization for 3D Neuronal Bilayer Formation.Many-body dynamics of chemically propelled nanomotors.
P2860
Q27308252-15747E19-B3B2-4F8C-B52E-001CB997B842Q27317825-071EBFD9-0E84-443B-A702-270095E44C5BQ27332217-014CF1B6-5B37-497A-BADB-FB3BC0A02D88Q27339185-05A00857-0883-486F-9F1B-75ED6E336E7FQ30528406-C7F48B18-FE3D-41F3-8F3A-B6E517D91D6CQ30541048-175077E0-5310-4443-AEAA-E8BE0A4299C5Q30559808-FF417015-3E5C-4696-AE14-58B4978B6A87Q30620997-6CB806F5-C5F9-48F4-B016-149142B04EC5Q30628333-FE45394E-AFB3-488A-9835-A7A8FBBDFF1AQ30827451-B6911251-69BB-4835-A52F-7F44E31E9C31Q33312847-8620FA5B-38CE-4419-86A7-BD3886223245Q33858372-29E2DD77-67C2-49A5-8B3E-32E53F39A919Q35560691-9F400148-F1A9-4181-8636-0E19ED3C9193Q36008322-DF77A121-5E18-4D94-8750-467E9E12E0F9Q36872301-B8AAABEC-3A3B-45FA-A3DA-1F96A5FC3643Q37340861-EED835B4-7410-4449-9B33-82E5BE0E3AE3Q37416735-D1268BD1-4783-47F8-A449-4ECE5F4F5392Q38742304-E35A956B-0646-4717-A293-C76FC74EB31DQ38805418-313398F3-AE12-4C3C-805E-991AC9BD8BEFQ39213338-B3BBD890-1F65-42F6-A462-256951728D49Q39382511-97345773-8830-4525-A808-F01AA430D60EQ39391521-7F8C6E64-9451-4F49-803A-77568C48729FQ39415740-B414BA78-C84C-4EC5-960C-8D753E02D448Q40315021-C2C21486-5CF4-45B6-9A64-98C48C965A67Q40329633-CB490615-B3CC-4F07-9C64-8CA93976E472Q41128318-64A87D20-5206-4FE7-9094-E032A2AA14C0Q41786261-4FF17110-3510-4CD9-A5A8-454561F4E25BQ42342832-2AC5BE41-D7CD-40E6-863C-320165B5E3E1Q42364763-A5BA7322-B13E-49D2-89B8-9FF29042F5E0Q43829698-8E619BC7-E640-4B54-B232-FC21521EB65DQ46226507-1C8F2E3A-81F8-4FCA-BB00-CE5409A74A90Q46856393-604A0AE5-DAB6-4125-AFAD-F31992D1B74FQ46926108-81CF7692-1E1D-4CCA-86AB-7CF26AC869D2Q47281256-74251187-03AF-408F-9526-41DC717D3F08Q47727844-53B655BC-D42E-48B0-83A0-DB49B5F3BD76Q47860177-91C82E2A-D107-4E94-9B99-1FD82DD92C39Q47869299-6CCADDAC-46F3-4636-846A-9F021D59738FQ47995234-42D34E3B-3436-4CD3-8001-3282A04FE970Q48028463-5991F6AE-461E-469D-8055-A59E0AF22221Q48235987-39C6CBB7-10FD-478B-B6BC-601684DCA2D3
P2860
description
2006 nî lūn-bûn
@nan
2006年の論文
@ja
2006年学术文章
@wuu
2006年学术文章
@zh
2006年学术文章
@zh-cn
2006年学术文章
@zh-hans
2006年学术文章
@zh-my
2006年学术文章
@zh-sg
2006年學術文章
@yue
2006年學術文章
@zh-hant
name
Nonequilibrium clustering of self-propelled rods.
@en
Nonequilibrium clustering of self-propelled rods.
@nl
type
label
Nonequilibrium clustering of self-propelled rods.
@en
Nonequilibrium clustering of self-propelled rods.
@nl
prefLabel
Nonequilibrium clustering of self-propelled rods.
@en
Nonequilibrium clustering of self-propelled rods.
@nl
P1433
P1476
Nonequilibrium clustering of self-propelled rods
@en
P2093
Fernando Peruani
Markus Bär
P304
P356
10.1103/PHYSREVE.74.030904
P407
P433
P577
2006-09-15T00:00:00Z
P698
P818
cond-mat/0604490