Relationships between water wettability and ice adhesion.
about
From superhydrophobicity to icephobicity: forces and interaction analysisDesigning durable icephobic surfaces.Activating the microscale edge effect in a hierarchical surface for frosting suppression and defrosting promotionMicroscopic receding contact line dynamics on pillar and irregular superhydrophobic surfaces.Self-cleaning of Surfaces: the Role of Surface Wettability and Dust Types.Crystallization seeds favour crystallization only during initial growthSuper-Hydrophobic/Icephobic Coatings Based on Silica Nanoparticles Modified by Self-Assembled Monolayers.Unraveling wetting transition through surface textures with X-rays: liquid meniscus penetration phenomena.Durable and scalable icephobic surfaces: similarities and distinctions from superhydrophobic surfaces.Bioinspired Interfacial Materials with Enhanced Drop Mobility: From Fundamentals to Multifunctional Applications.Bio-inspired design of ice-retardant devices based on benthic marine invertebrates: the effect of surface textureSurface micro/nanotopography, wetting properties and the potential for biomimetic icephobicity of skunk cabbage Symplocarpus foetidus.A predictive framework for the design and fabrication of icephobic polymersRice- and butterfly-wing effect inspired self-cleaning and low drag micro/nanopatterned surfaces in water, oil, and air flow.Fluid drag reduction and efficient self-cleaning with rice leaf and butterfly wing bioinspired surfaces.Room Temperature Characteristics of Polymer-Based Low Ice Adhesion Surfaces.Transparency and damage tolerance of patternable omniphobic lubricated surfaces based on inverse colloidal monolayers.Bioinspired Surfaces with Superwettability for Anti-Icing and Ice-Phobic Application: Concept, Mechanism, and Design.Multiscale crack initiator promoted super-low ice adhesion surfaces.Atomic-scale computational design of hydrophobic RE surface-doped Al2O3 and TiO2.Growth kinetics and morphology of snowflakes in supersaturated atmosphere using a three-dimensional phase-field model.Bioinspired Solid Organogel Materials with a Regenerable Sacrificial Alkane Surface Layer.Direct Imaging of Superwetting Behavior on Solid-Liquid-Vapor Triphase Interfaces.Nanoscale deicing by molecular dynamics simulation.A nano-frost array technique to prepare nanoporous PVDF membranes.New insight into icing and de-icing properties of hydrophobic and hydrophilic structured surfaces based on core-shell particles.Superhydrophobic Natural and Artificial Surfaces-A Structural Approach.Robust Hydrophobic Surfaces from Suspension HVOF Thermal Sprayed Rare-Earth Oxide Ceramics Coatings.Hydrate-phobic surfaces: fundamental studies in clathrate hydrate adhesion reductionPhotothermal trap utilizing solar illumination for ice mitigationRice and Butterfly Wing Effect Inspired Low Drag and Antifouling Surfaces: A ReviewBioinspired micro/nanostructured surfaces for oil drag reduction in closed channel flowInvestigation of intricate, amphiphilic crosslinked hyperbranched fluoropolymers as anti-icing coatings for extreme environments
P2860
Q24600989-7CF610D0-3A23-4AB7-9963-D7C0ED9FDDD7Q27334701-68B2B61E-8FBC-44B4-87AD-3930030DF28BQ28297439-61F5D406-ABA6-4B1B-AD0C-5B83D508688DQ30300825-0C7E0096-0BB9-453E-8CD1-9BE2B90C2588Q30830741-2BB0E582-108D-4F67-A9FD-ACDD2969F47FQ35775336-270A577C-CAE4-4413-875A-E72768E7DFA0Q36320699-12875628-634C-4773-8EF8-A2AA85D56E6CQ37576211-17449748-0FE3-4D6A-AA23-183F2043BB50Q38693621-86265B4A-30B0-4122-B8CE-0C48F6155BC9Q38729005-C3678DE7-E186-41C9-A1BC-7ACEEFD824E7Q39119375-F38041C3-CD84-4847-9A2D-BEFF8D9924B2Q39128347-2A4AAA51-A8D4-482C-BFB9-ACAF474C934DQ41694874-271362CB-4097-43DD-929D-C9A7DB23F434Q42006050-32B139B7-6E18-454C-A968-ECD5452197FBQ42007521-97103D6D-325A-48E8-A0BD-8767509F7B1DQ42323554-810A1531-9E1F-4C66-8977-2B04BD40FE62Q45768553-AECA4ACF-F40F-4A1E-988F-48B1158C9840Q47421407-CF9ACC6E-8B7A-48AC-8581-D3A60ECB4668Q47685321-1F2EE1CA-C4C6-4243-A33B-7117892E640BQ47874487-9B72A466-DD96-4212-ABDF-4E6BDD205DFCQ49820291-A1523926-C867-4B9D-BEB2-2CAE88B195CFQ50202873-21DA9586-E1D9-422F-B377-F8E575936B5BQ50225246-58F5D462-6A78-4554-A47A-E90B24C155A7Q51243300-6AF96142-C819-451F-B7EC-F0E9A32F4699Q53540690-E0CE47E5-69E0-40A4-B0F2-5B5455781A75Q53668192-14C1D122-D678-4C40-9B5D-9A0B41449695Q55010362-51661DB8-0A37-4404-A0F4-D080C0388DCCQ55100333-1B451784-67E7-44A5-9ADE-405A47686546Q57087411-95421737-B25C-437E-BB08-74DC57753742Q57091248-8028FE65-140B-4E2C-BD8C-E885A16965D8Q58799420-4D3C5956-5E77-405E-89DD-F5E669965F77Q58799477-D01EAF30-C116-4744-AFC2-1EAC7BC31134Q58874825-353FB9FD-83BF-4B30-AAD5-E73A8A214DEF
P2860
Relationships between water wettability and ice adhesion.
description
2010 nî lūn-bûn
@nan
2010年の論文
@ja
2010年論文
@yue
2010年論文
@zh-hant
2010年論文
@zh-hk
2010年論文
@zh-mo
2010年論文
@zh-tw
2010年论文
@wuu
2010年论文
@zh
2010年论文
@zh-cn
name
Relationships between water wettability and ice adhesion.
@en
type
label
Relationships between water wettability and ice adhesion.
@en
prefLabel
Relationships between water wettability and ice adhesion.
@en
P2093
P356
P1476
Relationships between water wettability and ice adhesion.
@en
P2093
Adam J Meuler
J David Smith
Kripa K Varanasi
Robert E Cohen
P304
P356
10.1021/AM1006035
P407
P577
2010-10-15T00:00:00Z