Suppressing the coffee stain effect: how to control colloidal self-assembly in evaporating drops using electrowetting
about
Optical tracking of nanoscale particles in microscale environments.BIOPHYSICAL PROPERTIES OF NUCLEIC ACIDS AT SURFACES RELEVANT TO MICROARRAY PERFORMANCE.Sample preconcentration inside sessile droplets using electrowettingDeposition and drying dynamics of liquid crystal dropletsDynamically controlled deposition of colloidal nanoparticle suspension in evaporating drops using laser radiation.Two-phase microfluidics in electrowetting displays and its effect on optical performance.The Fluid Joint: The Soft Spot of Micro- and Nanosystems.Formation of coffee-stain patterns at the nanoscale: The role of nanoparticle solubility and solvent evaporation rate.E-MALDI: optimized conditions during electrowetting-enhanced drop drying for MALDI-MS.Surfactant-driven flow transitions in evaporating droplets.Nonlinear oscillations of a sessile drop on a hydrophobic surface induced by ac electrowetting.Fingering inside the coffee ring.Acoustic suppression of the coffee-ring effect.Controlling and characterising the deposits from polymer droplets containing microparticles and salt.Manipulating the Coffee-Ring Effect: Interactions at Work.From coffee rings to coffee eyes.Self-assembly in an evaporating nanofluid droplet: rapid transformation of nanorods into 3D fibre network structures.Order-to-Disorder Transition in Ring-Shaped Colloidal StainsTemperature-Sensitive Hydrogel-Particle Films from Evaporating Drops
P2860
Q30383382-5EF23AA4-DB55-43DA-96BC-B8DCFD24FF40Q30415150-B7F5D0D2-DCBB-4974-B01C-4F119AA9CAC8Q30434974-A12F10D3-B340-43D5-8101-ED885D2B8856Q30854824-0292F66C-96CA-478D-BEC9-A4748312E4BDQ35994236-3D703ED4-204B-4F15-893A-A4C9B56790F6Q36576945-275A3E36-0FD7-40A6-894A-95E7C602B595Q38541034-D2BBBEB9-7543-49F3-B3ED-0ADE86993A45Q41933026-B581B65D-C23F-4C0E-8DB1-F9D6268BD378Q48063397-A7607E30-0386-48EB-BD61-3643C66224F7Q48638431-33A117F8-1236-40D1-91AA-025CC09D21D0Q51025085-A57FA1C8-1941-4EAE-A3CC-FD43ACA77194Q51257306-2004EB83-8BC1-4536-8596-33EA5B0C6BE8Q51812748-094C4C25-F5B2-4312-903E-39DB3AF9AAD1Q52668739-472D2EC4-865B-498A-896C-B6C99FAD4EA9Q53398269-A9DAC77E-42FD-44F6-AF30-4C7694A9DC5DQ53509462-4368C851-0405-4F84-ABCD-4687C6CA09A8Q53521753-E6EA0091-3E08-4FB5-A904-7D735A7EE02CQ56990571-071DE9D5-4529-4D0E-BEAC-7B3FECAC1052Q57341625-AF38A977-9D3E-4CE6-B0E7-7BC39E386561
P2860
Suppressing the coffee stain effect: how to control colloidal self-assembly in evaporating drops using electrowetting
description
im Januar 2011 veröffentlichter wissenschaftlicher Artikel
@de
wetenschappelijk artikel
@nl
наукова стаття, опублікована у 2011
@uk
name
Suppressing the coffee stain e ...... ing drops using electrowetting
@en
Suppressing the coffee stain e ...... ing drops using electrowetting
@nl
type
label
Suppressing the coffee stain e ...... ing drops using electrowetting
@en
Suppressing the coffee stain e ...... ing drops using electrowetting
@nl
prefLabel
Suppressing the coffee stain e ...... ing drops using electrowetting
@en
Suppressing the coffee stain e ...... ing drops using electrowetting
@nl
P2093
P2860
P356
P1433
P1476
Suppressing the coffee stain e ...... ing drops using electrowetting
@en
P2093
D. Mampallil Augustine
H. B. Eral
M. H. G. Duits
P2860
P356
10.1039/C1SM05183K
P577
2011-01-01T00:00:00Z