about
Ultrahigh stress and strain in hierarchically structured hollow nanoparticles.Influence of the cobalt particle size in the CO hydrogenation reaction studied by in situ X-ray absorption spectroscopy.Chemistry. All change for nanocrystals.Vacancy coalescence during oxidation of iron nanoparticles.High-performance thermoelectric nanocomposites from nanocrystal building blocksAdvanced Raman Spectroscopy of Methylammonium Lead Iodide: Development of a Non-destructive Characterisation Methodology.Structure, synthesis, and applications of TiO2 nanobelts.Compound Copper Chalcogenide Nanocrystals.Bottom-up engineering of thermoelectric nanomaterials and devices from solution-processed nanoparticle building blocks.A Self-Powered and Autonomous Fringing Field Capacitive Sensor Integrated into a Micro Sprinkler Spinner to Measure Soil Water Content.CuTe nanocrystals: shape and size control, plasmonic properties, and use as SERS probes and photothermal agents.Synthesis of quaternary chalcogenide nanocrystals: stannite Cu(2)Zn(x)Sn(y)Se(1+x+2y).Cobalt(II/III) redox electrolyte in ZnO nanowire-based dye-sensitized solar cells.Sulfidation of cadmium at the nanoscale.Metal ions to control the morphology of semiconductor nanoparticles: copper selenide nanocubes.Common aspects influencing the translocation of SERS to Biomedicine.Correction to "Electron Doping in Bottom-Up Engineered Thermoelectric Nanomaterials through HCl-Mediated Ligand Displacement".Tuning p-Type Transport in Bottom-Up-Engineered Nanocrystalline Pb Chalcogenides Using Alkali Metal Chalcogenides as Capping Ligands.Polymer-Enhanced Stability of Inorganic Perovskite Nanocrystals and Their Application in Color Conversion LEDs.Fe3O4@NiFexOy Nanoparticles with Enhanced Electrocatalytic Properties for Oxygen Evolution in Carbonate Electrolyte.Antimony-based ligand exchange to promote crystallization in spray-deposited Cu2ZnSnSe4 solar cells.Metal Oxide Aerogels with Controlled Crystallinity and Faceting from the Epoxide-Driven Cross-Linking of Colloidal Nanocrystals.Crystallographically Textured Nanomaterials Produced from the Liquid Phase Sintering of Bi xSb2- xTe3 Nanocrystal Building Blocks.Oxidation at the atomic scale.CuGaS₂ and CuGaS₂-ZnS Porous Layers from Solution-Processed Nanocrystals.Magnetic domains and surface effects in hollow maghemite nanoparticlesReaction Regimes on the Synthesis of Hollow Particles by the Kirkendall EffectReactivity of Au nanoparticles supported over SiO2 and TiO2 studied by ambient pressure photoelectron spectroscopyPolarity-Driven Polytypic Branching in Cu-Based Quaternary Chalcogenide NanostructuresColloidal synthesis and functional properties of quaternary Cu-based semiconductors: Cu2HgGeSe4Colloidal synthesis and thermoelectric properties of Cu2SnSe3nanocrystalsCore–Shell Nanoparticles As Building Blocks for the Bottom-Up Production of Functional Nanocomposites: PbTe–PbS Thermoelectric PropertiesCu2HgSnSe4 nanoparticles: synthesis and thermoelectric propertiesBottom-up processing of thermoelectric nanocomposites from colloidal nanocrystal building blocks: the case of Ag2Te–PbTeCrystallographic Control at the Nanoscale To Enhance Functionality: Polytypic Cu2GeSe3 Nanoparticles as Thermoelectric MaterialsCu2ZnGeSe4 Nanocrystals: Synthesis and Thermoelectric PropertiesEnhanced Photovoltaic Performance of Nanowire Dye-Sensitized Solar Cells Based on Coaxial TiO2@TiO Heterostructures with a Cobalt(II/III) Redox ElectrolyteSolution-growth and optoelectronic properties of ZnO:Cl@ZnS core–shell nanowires with tunable shell thicknessActive nano-CuPt3 electrocatalyst supported on graphene for enhancing reactions at the cathode in all-vanadium redox flow batteriesSolution-growth and optoelectronic performance of ZnO : Cl/TiO2and ZnO : Cl/ZnxTiOy/TiO2core–shell nanowires with tunable shell thickness
P50
Q33377924-ECB43D4E-883D-45E6-A4EE-36B3D281CAD2Q33443066-68923337-9B81-4136-A8B9-6FC085D4A64CQ34346497-2A036D0E-C4D7-413D-AAC3-505A33F2779CQ34659595-5838F523-3E8A-4461-B5B9-0C1D30F9FE90Q36674479-4A745FEC-00F2-4E78-95F0-3AF3674C22B9Q37369052-8573E893-707F-4491-B1CD-FB04FB94AF67Q38387983-DEF37ACC-704B-4C22-8EE2-80FEA4A24661Q39231751-24210941-F4A2-44B8-B841-7AFCB6769439Q39282380-DA3CA9DC-BBB3-46AF-AA97-10B6F0338037Q42010882-BB1E26AF-423E-4B4D-B052-E403D5E99B96Q42819912-98303AE5-1F5B-4E89-8160-2222F524C3A0Q43127986-BBB90EB9-284F-4468-A1B1-23C3FFD382DCQ45891579-7F93F811-28EB-4065-98C2-AAA3FCA7BA07Q46126163-5BDFD924-8F6B-4137-AC2D-1A042DDE6784Q46472991-3BF564E5-101F-4463-B9ED-44A343F31AF4Q47297899-A64A9FA1-8F9D-4B8A-9C30-232DF46364A5Q48742665-1882F339-9994-4C76-8CA6-5BC1DBAF83A2Q50054911-B79D65C2-DF91-4DFE-B77C-067A7B4CC26EQ50223011-8873C4EB-8BE1-4419-92CD-70BF73478934Q51113010-66889084-6EE6-470B-ABCE-DABBD681E0E7Q51777784-B0BF53C7-D02B-4072-AF0A-31439E587C78Q52578242-5C0C57BB-FBD8-4D8A-8809-00BDA6ED7AFDQ53825906-B6C3D96D-339E-40A2-A0D2-5C0BB1268E11Q53840145-E449CB3D-692D-4305-80E0-9B25C1DEB627Q55416974-FFD78169-44FF-4600-806F-C37CEE35448CQ56920979-D8EBCFDC-8BAA-4B95-9C0E-0B5C77AA65A7Q56920991-C1E44E4D-111D-4EA4-B610-D63965A364A1Q56920997-6D20C4EE-8D68-418C-8C75-3D53AC54C7ECQ57388922-1D28672C-506F-4702-86E2-CD0A4F016DD3Q57455001-983D9B45-C1BE-41A8-81DD-B26384BDFF19Q57455016-F3458907-8A6A-415A-8BC4-F4932653D416Q57455019-3F9DF3C8-D1FF-4861-B09A-CA8503827043Q57455023-EBF74172-7E7B-4F63-B86C-84820565EFE2Q57455052-C5C55173-0E2A-484D-A352-B17F0D8C430DQ57455056-A48B70A9-6D3D-4F26-883D-D31B6EF19596Q57455060-F1E626C9-7391-4E65-B7CB-979DCEA32F37Q57983927-019A50E0-F61D-4ABD-B77A-B039354F26F3Q57983941-76A099B7-E4B1-4242-BF5B-1B7BC24FCB86Q57983950-2E6C3BD9-AE49-4230-9DB3-4474B48D2E46Q57983965-CBD56696-E314-4590-B0FD-7C54F21A111E
P50
description
onderzoeker
@nl
researcher
@en
հետազոտող
@hy
name
Andreu Cabot
@ast
Andreu Cabot
@en
Andreu Cabot
@es
Andreu Cabot
@nl
type
label
Andreu Cabot
@ast
Andreu Cabot
@en
Andreu Cabot
@es
Andreu Cabot
@nl
prefLabel
Andreu Cabot
@ast
Andreu Cabot
@en
Andreu Cabot
@es
Andreu Cabot
@nl
P106
P1153
7004136864
P21
P31
P496
0000-0002-7533-3251