about
Design and Synthesis of Functional Silsesquioxane-Based Hybrids by Hydrolytic Condensation of Bulky TriethoxysilanesSurface hydrophobicity of slippery zones in the pitchers of two Nepenthes species and a hybrid.Directional Movement of Droplets in Grooves: Suspended or Immersed?Water and Ethanol Droplet Wetting Transition during Evaporation on Omniphobic SurfacesLayered superhydrophobic meshes for controlled drug releaseOil droplet self-transportation on oleophobic surfaces.Designing durable icephobic surfaces.Superhydrophobic cotton fabrics prepared by sol-gel coating of TiO2 and surface hydrophobizationPreparation of superhydrophobic surfaces on cotton textilesReducing the contact time of a bouncing dropSmart skin patterns protect springtails.Adaptable bioinspired special wetting surface for multifunctional oil/water separationSurface roughness rather than surface chemistry essentially affects insect adhesionTwo-Dimensional Fluorinated Graphene: Synthesis, Structures, Properties and ApplicationsMultifunctional substrate of Al alloy based on general hierarchical micro/nanostructures: superamphiphobicity and enhanced corrosion resistance.Uniting Superhydrophobic, Superoleophobic and Lubricant Infused Slippery Behavior on Copper Oxide Nano-structured SubstratesImparting amphiphobicity on single-crystalline porous materialsPancake bouncing on superhydrophobic surfacesDroplet mobility on lubricant-impregnated surfacesRobust omniphobic surfaces.Coexistence and transition between Cassie and Wenzel state on pillared hydrophobic surfaceBacterial biofilm shows persistent resistance to liquid wetting and gas penetration.Under-water superoleophobic glass: unexplored role of the surfactant-rich solvent.Super liquid-repellent gas membranes for carbon dioxide capture and heart-lung machines.Towards combinatorial mixing devices without any pumps by open-capillary channels: fundamentals and applicationsRole of Viscous Dissipative Processes on the Wetting of Textured Surfaces.Superhydrophobicity enhancement through substrate flexibility.Fluorine-free, liquid-repellent surfaces made from ionic liquid-infused nanostructured siliconFabrication of Superhydrophobic and Luminescent Rare Earth/Polymer complex Films.Review on the Processing and Properties of Polymer Nanocomposites and Nanocoatings and Their Applications in the Packaging, Automotive and Solar Energy FieldsAir-stable droplet interface bilayers on oil-infused surfaces.Lab-on-a-plate: extending the functionality of MALDI-MS and LDI-MS targets.Dry under water: comparative morphology and functional aspects of air-retaining insect surfaces.Separating oil-water nanoemulsions using flux-enhanced hierarchical membranes.Slippery Liquid-Infused Porous Surfaces that Prevent Microbial Surface Fouling and Kill Non-Adherent Pathogens in Surrounding Media: A Controlled Release Approach.Tailoring the grooved texture of electrospun polystyrene nanofibers by controlling the solvent system and relative humidity.Enriching libraries of high-aspect-ratio micro- or nanostructures by rapid, low-cost, benchtop nanofabrication.Biomimicry in textiles: past, present and potential. An overview.Self-healing of the superhydrophobicity by ironing for the abrasion durable superhydrophobic cotton fabrics.Reversible monolayer-to-crystalline phase transition in amphiphilic silsesquioxane at the air-water interface.
P2860
Q21296715-0B6D8D04-4437-414B-8A98-D14A4475375DQ27300790-F1157AF9-33FF-47CE-BECF-142FE26DF3BAQ27302836-6B2F08E8-040B-453E-9A9D-8CE59941F6BDQ27305148-C2A5677B-C5AC-4386-A1BF-CC1763ED853CQ27309990-D457D860-52BC-4868-A4F7-A35B5C366AD1Q27333841-D31ADE14-CBC8-428C-A936-BB653032D02CQ27334701-1FD2C5D7-7FDB-43D4-86BA-77C0DCEE3AF8Q28279697-D9231259-1FB5-4BA7-80FD-67E980A30180Q28279706-20FF4C82-4B8E-4502-AD47-6C12FC2B9D76Q28302333-6DCC71EB-294E-435F-9986-61F3AB966514Q28477303-919CF961-0CEC-4392-8E60-89BFBAB08CCBQ28584480-ED9A996C-2509-468A-B424-E1221A913DFEQ28820890-DBCAFAB8-D0CF-44AD-BC2D-91B566446FA5Q28821052-77754B2C-55D9-446D-AF87-7222FEBBE1D2Q28821254-84D3888F-D21B-4DF8-9D36-D3BF9EE47A22Q28821858-7D761BD5-C10D-4326-90FD-F20F7F8CCADDQ28822191-142F2CE7-BB23-4E84-A033-99A6B6E7E455Q29391720-DFF8ED76-0A89-43DE-89B0-A3ED1B466849Q29543767-5F3C7BC9-8E26-4563-9CAC-1FABF74A22C2Q30484754-FCE23761-3C66-4F65-90FA-04D734364841Q30487892-0FDDD5D4-C501-4476-8C8F-95D194966A0DQ30497965-D6412AF1-1DC7-4BFB-A4E7-C11C2968C7C1Q30539984-7CE14B52-9E1D-47F8-A8B4-88AB7F67168FQ30548790-EB362C63-ED30-49D6-ADFC-B169D91C7563Q30655353-D6C3612F-A5A3-4CBF-8A64-3D45B46C6355Q30665883-4AB0739E-F65A-4355-A221-A18E4F437E9BQ30830136-5A624E18-EFE8-4BF2-9DCC-826856FDCC7BQ30834533-79209A29-9B1D-4356-A445-C18694DFA2A8Q30836286-A144586F-62CC-4DE5-A169-ED89B9760567Q33611934-4F917A83-4DC3-4F60-B9EB-F2AD5F4DF7F0Q33694503-FD9D1B86-A9AB-4AF7-804A-6C72E48033E8Q33799571-97911542-F0E6-4E7E-9692-AF6320BF037CQ33811070-BEC96B83-3333-48BA-9EE3-35E352BD2FAFQ33827173-4E3234BC-7C7B-43B5-9C71-1DAF4A6CC399Q33898806-E9DC4FF6-2BB1-467B-A160-C5E621C3893CQ33948117-3DA3CD5E-E324-420A-A5E0-C6DD54CBD6A8Q34142610-19D217D4-9FCB-4EE2-B002-113BF5B9297BQ35014493-203ACC9C-F3AE-46F5-AB8B-950C106DC092Q35019968-EAC98151-4738-499A-BE6F-7A7903C32F7EQ35089436-5697D428-14A3-40F4-8512-7A1D814BCF21
P2860
description
2007 nî lūn-bûn
@nan
2007年の論文
@ja
2007年学术文章
@wuu
2007年学术文章
@zh
2007年学术文章
@zh-cn
2007年学术文章
@zh-hans
2007年学术文章
@zh-my
2007年学术文章
@zh-sg
2007年學術文章
@yue
2007年學術文章
@zh-hant
name
Designing superoleophobic surfaces.
@en
Designing superoleophobic surfaces.
@nl
type
label
Designing superoleophobic surfaces.
@en
Designing superoleophobic surfaces.
@nl
prefLabel
Designing superoleophobic surfaces.
@en
Designing superoleophobic surfaces.
@nl
P2093
P356
P1433
P1476
Designing superoleophobic surfaces.
@en
P2093
Anish Tuteja
Gregory C Rutledge
Joseph M Mabry
Minglin Ma
Robert E Cohen
Sarah A Mazzella
Wonjae Choi
P304
P356
10.1126/SCIENCE.1148326
P407
P577
2007-12-01T00:00:00Z