about
Measuring and overcoming limits of the Saffman-Delbrück model for soap film viscositiesEmergent complexity of the cytoskeleton: from single filaments to tissuePassive one-particle microrheology of an unentangled polymer melt studied by molecular dynamics simulation.Intracellular microrheology of motile Amoeba proteus.Fast fluorescence laser tracking microrheometry. I: instrument development.Correlated motions of two hydrodynamically coupled particles confined in separate quadratic potential wells.Correlated fluctuations of microparticles in viscoelastic solutions: quantitative measurement of material properties by microrheology in the presence of optical traps.Counterion-dependent microrheological properties of F-actin solutions across the isotropic-nematic phase transition.Longitudinal measurement of extracellular matrix rigidity in 3D tumor models using particle-tracking microrheology.Viscoelastic transition and yield strain of the folded protein.Colloid surface chemistry critically affects multiple particle tracking measurements of biomaterialsMechanical properties of Xenopus egg cytoplasmic extracts.Actin-driven cell dynamics probed by Fourier transform light scattering.The role of Arabidopsis Actin-Related Protein 3 in amyloplast sedimentation and polar auxin transport in root gravitropism.Evaluation and correction for optical scattering variations in laser speckle rheology of biological fluidsThe consensus mechanics of cultured mammalian cells.Bio-microrheology: a frontier in microrheology.Measurement of the nonlinear elasticity of red blood cell membranes.Fluctuation Analysis of Centrosomes Reveals a Cortical Function of Kinesin-1.Active multi-point microrheology of cytoskeletal networks.Effects of cytoskeletal disruption on transport, structure, and rheology within mammalian cells.Mechanical properties of cellularly responsive hydrogels and their experimental determination.Let's push things forward: disruptive technologies and the mechanics of tissue assembly.Local mechanical response in semiflexible polymer networks subjected to an axisymmetric prestress.Response of a polymer network to the motion of a rigid sphere.Refolding hydrogels self-assembled from N-(2-hydroxypropyl)methacrylamide graft copolymers by antiparallel coiled-coil formation.Two-bead microrheology: modeling protocols.The liquid-glass-jamming transition in disordered ionic nanoemulsions.Dynamics of viscoelastic membranes.Nanorheology of viscoelastic shells: applications to viral capsids.Two-point particle tracking microrheology of nematic complex fluids.Combined macro- and microrheometer for use with Langmuir monolayers.Microrheological detection of protein unfolding.Spatially resolved microrheology of heterogeneous biopolymer hydrogels using covalently bound microspheres.Probe size effects on the microrheology of associating polymer solutions.Surface adsorption and hopping cause probe-size-dependent microrheology of actin networks.Direct verification of the fluctuation-dissipation relation in viscously coupled oscillators.Scale dependence of the mechanics of active gels with increasing motor concentration.Asymptotic analysis of tracer diffusivity in nonadsorbing polymer solutions.Universal scaling of correlated diffusion in colloidal monolayers.
P2860
Q27310521-153243B4-F4AB-4DA9-BDF4-57C29C216D2AQ28238533-2D138C3F-3148-4BA2-95E8-69659940C2DFQ30317085-D4825656-3919-42A6-B876-CF376C30CFDBQ30481558-F391887D-6FAA-4B95-997E-28F21ACFA0E9Q30491254-CEF1C090-6932-4120-8710-499EE71CD1C0Q30818562-FBEFDA63-F123-466E-96EA-CE0EC36856E4Q33253799-7DD2224B-ED4F-4AD3-A89D-1E51E32D6F95Q33365682-C9236A52-7856-4222-8750-0C98D0CE7407Q33872423-2F35F1EB-6E31-4401-84A4-D36F8E7A41ADQ34102937-D4A7C2DA-D7BD-4C0A-8D73-D1D0A4F38950Q34186126-29DF21DB-B5B8-4A03-A0DB-4AE68BDED74FQ34188623-737D35FB-C8CC-4320-8610-9238E81ACB9FQ34420569-5A7683EC-11F7-446A-BE30-3FD2977518C5Q34678042-1E09618B-06C3-4F66-BBE9-8E598806EFD4Q34738290-02842CAA-3D36-4C08-8C41-B4F48C8812F5Q34772019-285519C7-89FA-46CE-B55C-E3FBF921BD26Q35128908-3E8590E6-E521-4360-85DC-18BC3BC9A391Q35954673-E8F5A1C2-62FC-4658-AA67-744BA6DCB78CQ36045109-A71BD329-0383-4935-8B8C-12EE6DCBF813Q36059643-7933D85C-111A-4767-8DE3-4A621F06642EQ37379423-7490BBF1-2940-4EE6-A3C8-36166E4BBE8FQ37475567-0DF268AB-6703-4E92-98D6-4731B7161669Q38125912-26483C0B-AD32-4FE1-9972-FEA71F44EEE1Q39351080-9E918AE2-EEEC-4F52-9FAD-E8ADF25FF084Q40958123-7BC290A2-2C72-485B-9C1C-E9D01302110EQ42426685-A58A1CBE-41CC-4C8C-929E-AEF32406ACB6Q43116500-BBDB950D-71C8-4E5B-842E-9EFE1D3DD80BQ43969817-23EE16E3-58B5-43E9-AAB5-C09972CADD75Q44058133-4FF094F8-F5A3-425E-8345-A9C3A159D54CQ46131990-979532CF-9187-4F40-B3A7-6FDE193AC038Q46587829-532A2F10-3A0E-4825-9826-7CBA650AFE22Q46650138-17A05001-B781-4E79-A587-3F357502CDF6Q46871921-A0A9763E-E607-4260-B2F9-A91B1CFAC549Q46976595-13E0E1C7-6DB2-45C3-9966-82E02B87B1DDQ47173922-B8A0B9BB-E224-4F3F-9D6E-B6C3B10B5F89Q47375652-8713EC3C-AA77-448E-9558-90C1335C2358Q47559388-407C343E-89ED-40A9-B2B7-D637321EC0B7Q47738409-B44AFEB3-9B68-4D7B-B9E9-A590BDAEA597Q47951214-5A3CFAEB-A1BA-4767-97FF-1835CE6BA88EQ48705733-3FA8CCF1-7252-418C-8FF2-17FE514D1572
P2860
description
2000 nî lūn-bûn
@nan
2000 թուականի Օգոստոսին հրատարակուած գիտական յօդուած
@hyw
2000 թվականի օգոստոսին հրատարակված գիտական հոդված
@hy
2000年の論文
@ja
2000年学术文章
@wuu
2000年学术文章
@zh-cn
2000年学术文章
@zh-hans
2000年学术文章
@zh-my
2000年学术文章
@zh-sg
2000年學術文章
@yue
name
One- and Two-Particle Microrheology
@ast
One- and Two-Particle Microrheology
@en
One- and Two-Particle Microrheology
@nl
type
label
One- and Two-Particle Microrheology
@ast
One- and Two-Particle Microrheology
@en
One- and Two-Particle Microrheology
@nl
prefLabel
One- and Two-Particle Microrheology
@ast
One- and Two-Particle Microrheology
@en
One- and Two-Particle Microrheology
@nl
P2860
P3181
P1476
One- and Two-Particle Microrheology
@en
P2093
Alex J. Levine
T. C. Lubensky
P2860
P304
P3181
P356
10.1103/PHYSREVLETT.85.1774
P407
P577
2000-08-21T00:00:00Z
P698
P818
cond-mat/0004103