about
Cutting through the complexity of cell collectivesMEDYAN: Mechanochemical Simulations of Contraction and Polarity Alignment in Actomyosin NetworksImmersed Boundary Simulations of Active Fluid DropletsElectric-field-induced assembly and propulsion of chiral colloidal clustersTunable dynamics of microtubule-based active isotropic gelsLight-activated self-propelled colloidsDisorder-mediated crowd control in an active matter system.Stabilization of active matter by flow-vortex lattices and defect ordering.Directional reversals enable Myxococcus xanthus cells to produce collective one-dimensional streams during fruiting-body formation.Hysteretic dynamics of active particles in a periodic orienting field.Emergent complexity of the cytoskeleton: from single filaments to tissueActive Brownian particles and run-and-tumble particles separate inside a maze.Water reservoir maintained by cell growth fuels the spreading of a bacterial swarm.Meso-scale turbulence in living fluids.Topological structure dynamics revealing collective evolution in active nematics.Living liquid crystals.Fluid flows created by swimming bacteria drive self-organization in confined suspensionsPhysical basis of spindle self-organizationSuperconfinement tailors fluid flow at microscalesHydrodynamic schooling of flapping swimmers.Symmetry-breaking phase transitions in highly concentrated semenLocal equilibrium in bird flocks.Dynamic and programmable self-assembly of micro-rafts at the air-water interface.Social interactions dominate speed control in poising natural flocks near criticality.Anomalous diffusion and q-Weibull velocity distributions in epithelial cell migrationFlocking at a distance in active granular matter.Aspects of the density field in an active nematicEmergent mechanics of biological structures.Leadership, collective motion and the evolution of migratory strategies.Dynamical freezing of active matterActive actin gelsCrystallization and flow in active patch systems.Activity induces traveling waves, vortices and spatiotemporal chaos in a model actomyosin layer.Control of active liquid crystals with a magnetic field.Hysteresis, reentrance, and glassy dynamics in systems of self-propelled rods.Multiscale modeling and simulation of microtubule-motor-protein assemblies.Actomyosin contractility rotates the cell nucleus.Using active colloids as machines to weave and braid on the micrometer scale.Spontaneous mirror-symmetry breaking induces inverse energy cascade in 3D active fluids.Chromosome positioning from activity-based segregation.
P2860
Q26823351-5D687980-E7E2-4101-8238-A70DFD7E2E60Q27316439-B738623E-FC33-4282-8C70-FAEB11059B40Q27323153-A7FBE9FA-BC6E-41C1-9252-A4218B54A26AQ27324244-97ECE580-F356-4A56-AD8E-9F740C84BC8EQ27324548-18300F85-F612-4BFA-8E5A-B67F87748AB3Q27324690-0EC46526-638B-4E29-B40E-9CE3F49D48FFQ27325325-3020E6F8-8A27-4DCA-82D8-8C81F8EA3025Q27334069-74F55225-C077-4566-9813-DA991646C0BFQ27342758-9FE0866C-B7A7-44FE-96C7-FFB85E29A2DFQ27342847-314B5E06-F444-4470-8D72-7162C803F6AAQ28238533-A684B175-54FF-45E0-9958-8381C76FA579Q28820753-EEA3824B-A193-4754-BC91-DBD5E89E8792Q30511081-A63F1A45-BD2D-4C4A-BA48-7E76D79F7F02Q30524843-B71F71C5-DE6C-448F-98DB-55F9BF878B22Q30569944-1B217E78-AC15-4B98-AB5A-D8E7738164EBQ30570484-7E1F67B1-86BA-4B63-95C3-0556F4209095Q30584254-52978564-6661-4590-B4AA-39A2324D209AQ30612941-BB0A090C-B47D-4945-B462-5D73AE9C0D6DQ30656490-5FF3EB73-3F99-4559-9FA2-64DB6ADA145FQ30667549-535AA312-5575-43CA-8280-3905C5BE3314Q30827451-5DAAFF15-36C0-4A8B-AD87-8AE881247397Q30830408-D0F0C264-70F6-4DAC-90FD-5261D121CE27Q30853228-F0F152ED-C317-4D65-8838-BCD2C911D520Q33665528-FE6DDF7B-D017-411B-A909-8918A42632B7Q33897719-6C7E0963-95B7-4CBD-A1DF-9B0153F4D6ACQ34436493-20B40BAF-01A1-4C42-8D58-10B1812204C8Q34469326-69B0822F-EA7A-4F2A-842E-7CAB72807CECQ34504139-295F1EC8-86B0-4540-815A-289B2CE4DFD7Q35278374-99EAD74C-7C08-4A6D-9CEF-A7854AAA936EQ35585859-DF0AE0D4-909F-4551-9108-4B39710A6A51Q35793449-C79F8D36-90C9-4EDD-B2AF-C9B6A761F6A5Q36250965-1A05F140-1D2B-4F38-A987-0FA8FBF33982Q36579677-A8235BB0-45E2-44FD-8DF3-314A7B3FCE32Q36931085-9E51F857-2992-48A9-B0B5-E3BB7B01DE29Q37340861-AD18832B-A75E-48C4-B5B7-3BE46142EC66Q37371980-F2A9705F-A178-46C0-AFFD-DF6E76BFFF2EQ37497746-CCAF0211-2AAE-4845-9EB9-F3F1068A72D8Q37589918-67E129DD-A23B-47CE-B7AD-333EB74BA298Q37682404-5E1F0312-19F3-4BFB-8B4D-F733529DDD3DQ37701278-F4B9ABF5-5634-40D5-B6B3-A8630C9D4550
P2860
description
wetenschappelijk artikel
@nl
наукова стаття, опублікована в серпні 2010
@uk
name
The Mechanics and Statistics of Active Matter
@en
The Mechanics and Statistics of Active Matter
@nl
type
label
The Mechanics and Statistics of Active Matter
@en
The Mechanics and Statistics of Active Matter
@nl
prefLabel
The Mechanics and Statistics of Active Matter
@en
The Mechanics and Statistics of Active Matter
@nl
P1476
The Mechanics and Statistics of Active Matter
@en
P2093
Sriram Ramaswamy
P304
P356
10.1146/ANNUREV-CONMATPHYS-070909-104101
P407
P577
2010-08-10T00:00:00Z