about
Contrasting micro/nano architecture on termite wings: two divergent strategies for optimising success of colonisation flightsRemoval mechanisms of dew via self-propulsion off the gecko skinNanotopographic substrates of poly (methyl methacrylate) do not strongly influence the osteogenic phenotype of mesenchymal stem cells in vitroUnder-water superoleophobic glass: unexplored role of the surfactant-rich solvent.Role of Viscous Dissipative Processes on the Wetting of Textured Surfaces.Beyond Cassie equation: local structure of heterogeneous surfaces determines the contact angles of microdroplets.Measuring air layer volumes retained by submerged floating-ferns Salvinia and biomimetic superhydrophobic surfaces.Bacterial attachment and biofilm formation on surfaces are reduced by small-diameter nanoscale pores: how small is small enough?Functional superhydrophobic surfaces made of Janus micropillarsA theoretical approach to the relationship between wettability and surface microstructures of epidermal cells and structured cuticles of flower petals.Non-adhesive lotus and other hydrophobic materials.Advanced understanding of stickiness on superhydrophobic surfaces.Wetting theory for small droplets on textured solid surfaces.The Influence of New Hydrophobic Silica Nanoparticles on the Surface Properties of the Films Obtained from Bilayer HybridsHygiene and cleanability: a focus on surfaces.Wetting transitions on biomimetic surfaces.Characterisation of surface wettability based on nanoparticles.Superhydrophobic nanocoatings: from materials to fabrications and to applications.Self-Assembled Monolayers as Patterning Tool for Organic Electronic Devices.Surface structure and wetting characteristics of Collembola cuticles.Sessile Nanodroplets on Elliptical Patches of Enhanced Lyophilicity.A dual layer hair array of the brown lacewing: repelling water at different length scales.Enhancement of surface wettability via the modification of microtextured titanium implant surfaces with polyelectrolytes.Temperature Assisted in-Situ Small Angle X-ray Scattering Analysis of Ph-POSS/PC Polymer Nanocomposite.Hemocompatibility of Superhemophobic Titania Surfaces.Layers of air in the water beneath the floating fern Salvinia are exposed to fluctuations in pressure.A numerical study of droplet dynamic behaviors on a micro-structured surface using a three dimensional color-gradient lattice Boltzmann model.Topography- and topology-driven spreading of non-Newtonian power-law liquids on a flat and a spherical substrate.Nanodrop on a nanorough solid surface: density functional theory considerations.Wetting at the nanoscale: A molecular dynamics study.A nonmonotonic dependence of the contact angles on the surface polarity for a model solid surface.Droplet on a regularly patterned solid. Wenzel's regime and meso-scale roughness.Quantitative phase-field modeling for wetting phenomena.Nanodrop on a smooth solid surface with hidden roughness. Density functional theory considerations.Droplet spreading on chemically heterogeneous substrates.Fouling of nanostructured insect cuticle: adhesion of natural and artificial contaminants.Wettability versus electrostatic forces in fibronectin and albumin adsorption to titanium surfacesSpherical and core-shell fluorinated polyacrylate latex particles: preparation and characterizationGeometric confinement of directly deposited features on hydrophilic rough surfaces using a sacrificial layerPolymer porous interfaces with controllable oil adhesion underwater
P2860
Q27321540-36086B7D-AAB2-41E4-8EB1-BC5EFCB68C43Q27342929-77BEEDAA-A052-492D-92BD-A845D1BAB16FQ28540330-34BF49C0-FE93-44DF-8FA1-4F08DCBC76BDQ30539984-C43E9BCF-9DE8-4193-9B99-565B089CE1DBQ30665883-1198CD2C-0B12-484F-AB16-4F4CCD00EA64Q30843518-47531549-941A-4381-BEC8-4A2E2827CF11Q31171443-4544C701-F4C6-43B6-A124-D7D1C75FFF81Q33914774-0216B190-1F87-4E71-8854-8606DD076B1FQ35443032-CC71E696-CFCD-4ED4-8E79-6B2179DA6E31Q35529468-01C6E65F-8C0C-4B8F-B058-403CB49E79BFQ37055958-1B1EE59A-38B2-4B96-A452-FE38E0A82F14Q37326215-804181B1-4FA4-4254-BB7F-63D56848002CQ37449273-D5B71D72-5B45-4F06-AE39-B97B15CF1CCBQ37676219-004034C9-B36B-42AF-AA1F-093826D6E5E9Q37778793-560E0841-F3BF-43F4-9BEB-1C77F8582EEFQ37790512-1F606DF1-CCF1-4F92-B360-BA4925D76E89Q37990835-0727AF06-F821-42D4-A857-1F52C394FB07Q38376104-F3139FC3-97BB-4F76-AF7C-C2C491DD3E5CQ39119241-B2E435FF-1009-48A5-A1B7-8BF979CBC79CQ41909420-505FF75A-7688-42B4-829C-5610F0735203Q42005011-6E65577F-5657-4B20-AECF-85B21305A0F0Q42058268-798E9354-AA92-47B5-896C-37D86CD11EC4Q42069765-90E7A789-87AE-4F00-8296-6280AB78D16AQ42412622-93A9182B-B94E-474F-812F-259A039B8C27Q45863111-83B075FE-5F60-491A-A1C7-4B3E1E6B4877Q46880189-C3F260F7-7721-48F9-B1F7-3DFF65F21249Q47194887-9B0A53EF-3768-4197-9920-FB4ABC9704BCQ47559792-332FFB91-E48B-476F-A7D1-A1E60F94EE1CQ47577564-6E6BAC9B-2047-428B-B16D-F14321219F75Q48091721-B59604AD-E8EC-4B40-84A3-557C493AF99AQ48225460-6C3CDF48-7F62-4027-8983-143B7D035331Q50896931-1FF85579-6198-408C-8A9F-7F5811414B5EQ50932139-4CAB7334-F80F-49BF-AE19-08CC4211FC9BQ50934653-1960B917-899F-4A2C-8D23-C63E66A28C65Q51503329-8D873385-A1B4-447E-A755-16B6CA165DD1Q52730690-35FB449F-BB90-47F9-87BE-9955AA9382ABQ56925051-54B8E77E-0C00-479D-98E2-38DFCCF9585DQ57347354-3CFE78CC-D648-4828-98BA-708D2C351201Q57348685-E032E7E9-EE91-4E75-8D7D-4321B1BBC907Q57366599-AB75F0D5-95A5-4E62-A80F-810F45A1A08F
P2860
description
2007 nî lūn-bûn
@nan
2007 թուականի Մարտին հրատարակուած գիտական յօդուած
@hyw
2007 թվականի մարտին հրատարակված գիտական հոդված
@hy
2007年の論文
@ja
2007年論文
@yue
2007年論文
@zh-hant
2007年論文
@zh-hk
2007年論文
@zh-mo
2007年論文
@zh-tw
2007年论文
@wuu
name
How Wenzel and cassie were wrong
@ast
How Wenzel and cassie were wrong
@en
How Wenzel and cassie were wrong
@nl
type
label
How Wenzel and cassie were wrong
@ast
How Wenzel and cassie were wrong
@en
How Wenzel and cassie were wrong
@nl
prefLabel
How Wenzel and cassie were wrong
@ast
How Wenzel and cassie were wrong
@en
How Wenzel and cassie were wrong
@nl
P3181
P356
P1433
P1476
How Wenzel and cassie were wrong
@en
P2093
Lichao Gao
Thomas J McCarthy
P304
P3181
P356
10.1021/LA062634A
P407
P577
2007-03-27T00:00:00Z