about
Interfacial activity of metal β-diketonato complexes: in situ generation of amphiphiles by water coordination.Color from hierarchy: Diverse optical properties of micron-sized spherical colloidal assemblies.Transparent antifouling material for improved operative field visibility in endoscopy.Advances in colloidal assembly: the design of structure and hierarchy in two and three dimensions.A colloidoscope of colloid-based porous materials and their uses.Platinum nanoparticles from size adjusted functional colloidal particles generated by a seeded emulsion polymerization process.Role of Flagella in Adhesion of Escherichia coli to Abiotic Surfaces.Engineered disorder and light propagation in a planar photonic glass.Transparency and damage tolerance of patternable omniphobic lubricated surfaces based on inverse colloidal monolayers.Arrays of size and distance controlled platinum nanoparticles fabricated by a colloidal method.Anisotropic Self-Assembly from Isotropic Colloidal Building Blocks.Ionic-Liquid-Infused Nanostructures as Repellent Surfaces.Preventing mussel adhesion using lubricant-infused materials.Interfacial arrangement and phase transitions of PNiPAm microgels with different crosslinking densities.Smart Optical Composite Materials: Dispersions of Metal-Organic Framework@Superparamagnetic Microrods for Switchable Isotropic-Anisotropic Optical Properties.Bottom-Up Assembly of Silica and Bioactive Glass Supraparticles with Tunable Hierarchical Porosity.The Optical Janus Effect: Asymmetric Structural Color Reflection Materials.Ordered nanopore arrays with large interpore distances via one-step anodization.Combining Bottom-Up Self-Assembly with Top-Down Microfabrication to Create Hierarchical Inverse Opals with High Structural Order.Hierarchical structural control of visual properties in self-assembled photonic-plasmonic pigments.Directional wetting in anisotropic inverse opals.Surface Patterning with SiO@PNiPAm Core-Shell ParticlesAmphiphile-Induced Anisotropic Colloidal Self-AssemblyOrdered Arrays of Gold Nanostructures from Interfacially Assembled Au@PNIPAM Hybrid NanoparticlesThree-Dimensional Electrochemical Axial Lithography on Si Micro- and Nanowire ArraysPlasmon Hybridization in Stacked Double Crescents Arrays Fabricated by Colloidal LithographyReusable Localized Surface Plasmon Sensors Based on Ultrastable NanostructuresLaterally Patterned Ultraflat SurfacesMagic number colloidal clusters as minimum free energy structuresSwitching light with light – advanced functional colloidal monolayersMagnetic Polymer/Nickel Hybrid Nanoparticles Via Miniemulsion PolymerizationFormation of Highly Ordered Alloy Nanoparticles Based on Precursor-Filled Latex SpheresFrom soft to hard: the generation of functional and complex colloidal monolayers for nanolithographyInterplay of Mie and Bragg resonances in partly ordered monolayers of colloidal spheresOnline Monitoring of Styrene Polymerization in Miniemulsion by Hyperpolarized 129Xenon NMR SpectroscopyProbing guided modes in a monolayer colloidal crystal on a flat metal filmA Convenient Method to Produce Close- and Non-close-Packed Monolayers using Direct Assembly at the Air-Water Interface and Subsequent Plasma-Induced Size ReductionPlasmon hybridization and strong near-field enhancements in opposing nanocrescent dimers with tunable resonancesWafer-Scale Fabrication of Ordered Binary Colloidal Monolayers with Adjustable StoichiometriesAccurate Elemental Analysis of Metal-Containing Polymer Latexes Using ICP-Optical Emission Spectrometry
P50
Q33921772-D6A0C288-D48C-41E5-914F-15BFE18424F2Q36055523-E776936E-3434-4B75-B1F3-E0011B2E6BBAQ36149499-A971C62A-0650-49C9-829F-39BBA1F574EFQ38534139-0D0083D2-86B6-4ABA-987E-85247CE902F7Q38591270-FE11D7B9-A980-4C71-A0ED-AEE4528E753FQ38671980-685BAAB7-F7B9-4BC4-AE81-B3CDAB8E26C7Q40971559-B38F10E3-C162-4022-84CD-9E4D6D6E14AAQ42253529-4D1FC29B-5C74-4FDA-A42E-18A37D07806BQ45768553-DC3F92E5-C1CC-4053-A1E1-71EF6E1CE0BFQ47377573-049D49FF-AA6B-41D3-89EF-CD58B097F9BFQ47598891-4CF3E43C-E950-4722-9F86-F26117DCB7CCQ47706629-AF76F808-DFAF-461D-B969-86C1341EC560Q47782631-56808488-3E53-4ED4-85AF-EE352910E7CBQ47805294-A50C5C43-E7FC-4A96-BDF6-8077DD1FC23FQ48163863-45FBA9F9-4BDE-4437-9832-FB73C0CC6987Q48296515-F77A81D9-9E1F-4599-9364-4F554151FC58Q50851244-20EA6141-9540-4802-A6EF-D39AB74BBBE1Q52562457-1C6AC21E-6E25-4EEA-9B68-399EE59C6EEAQ53217060-A352F311-454E-46AF-A47F-23B1F8155581Q53391201-DFF25470-29FB-4079-8A3E-C4C7D95B5EB0Q53522615-609A57CD-C4DA-4A96-BAD3-77B764BFE080Q57063486-ECFFC568-29C5-476F-8F79-990F6E3347AAQ57358408-E36B95E3-D9B4-4BDD-A91E-24717EA9A3EEQ57361008-D8F95788-A072-49E6-B5EF-9F17C8A1E794Q57788353-F90213DE-796D-41BB-9790-7C89CA791F07Q58305272-EEEFCCD9-D8D6-4779-9314-D8282DE4AED2Q58305281-7D59BB02-77A1-4AA4-871B-2268B3F159EBQ58305310-8941F870-0C57-4F89-A422-05D5A97B4A78Q59789931-93CEC103-8D83-4C5D-B4E0-2B12F4D66C67Q62590099-0CA85E89-AA77-481D-BA52-EC2E65C32B67Q62590222-B50703B6-9AD7-4262-A388-00DC6F7D7EA7Q62590385-82F5EF2B-9044-4A0D-A7A4-A52F5DF34F92Q62590388-2C27240F-88BD-47D9-8476-C1CA94A2BC85Q62590440-75D11A16-73BB-4C52-89DC-7419F058855BQ62590508-B2C17662-EF66-4320-9503-411A668467E2Q62590546-9D7354BC-7BD5-44B3-A262-429C7D74B36BQ62590693-F4749C0D-4442-4153-8395-EF8AFE2574F3Q62590840-7E90E297-BECC-4D23-B779-C9EDDABC27D8Q62590894-B9CF8251-D51D-454D-A0BA-CB0601AB9147Q62590906-B5B3DC61-910E-4305-AF92-0FA27C13F3CB
P50
description
hulumtues
@sq
onderzoeker
@nl
researcher
@en
ricercatore
@it
հետազոտող
@hy
name
Nicolas Vogel
@ast
Nicolas Vogel
@en
Nicolas Vogel
@es
Nicolas Vogel
@sl
نيكولا فوغل
@ar
type
label
Nicolas Vogel
@ast
Nicolas Vogel
@en
Nicolas Vogel
@es
Nicolas Vogel
@sl
نيكولا فوغل
@ar
prefLabel
Nicolas Vogel
@ast
Nicolas Vogel
@en
Nicolas Vogel
@es
Nicolas Vogel
@sl
نيكولا فوغل
@ar
P214
P106
P1153
17347266600
P21
P214
P31
P496
0000-0002-9831-6905
P734
P735
P7859
viaf-81693881