about
Sub-Micrometer Magnetic Nanocomposites: Insights into the Effect of Magnetic Nanoparticles Interactions on the Optimization of SAR and MRI Performance.Spiked gold beads as substrates for single-particle SERS.Gold nanorods 3D-supercrystals as surface enhanced Raman scattering spectroscopy substrates for the rapid detection of scrambled prionsHigh-Temperature Magnetism as a Probe for Structural and Compositional Uniformity in Ligand-Capped Magnetite Nanoparticles.Growth of pentatwinned gold nanorods into truncated decahedra.Adsorption of marine phycotoxin okadaic acid on a covalent organic framework.Combination of Microfluidic Loop-Mediated Isothermal Amplification with Gold Nanoparticles for Rapid Detection of Salmonella spp. in Food Samples.Magnetite Nanoparticles for Stem Cell Labeling with High Efficiency and Long-Term in Vivo Tracking.Multiresponsive hybrid colloids based on gold nanorods and poly(NIPAM-co-allylacetic acid) microgels: temperature- and pH-tunable plasmon resonance.A supramolecular strategy based on molecular dipole moments for high-quality covalent organic frameworks.Up-scaling the synthesis of Cu₂O submicron particles with controlled morphologies for solar H₂ evolution from water.Influence of the separation procedure on the properties of magnetic nanoparticles: Gaining in vitro stability and T1–T2 magnetic resonance imaging performanceAu@Ag Nanoparticles: Halides Stabilize {100} FacetsAtomic-scale determination of surface facets in gold nanorodsThe Crystalline Structure of Gold Nanorods Revisited: Evidence for Higher-Index Lateral FacetsOvergrowth and Crystalline Structure of Gold NanorodsRapid Epitaxial Growth of Ag on Au Nanoparticles: From Au Nanorods to Core-Shell Au@Ag OctahedronsModeling the Optical Response of Highly Faceted Metal Nanoparticles with a Fully 3D Boundary Element MethodChemical Sharpening of Gold Nanorods: The Rod-to-Octahedron TransitionGemini-Surfactant-Directed Self-Assembly of Monodisperse Gold Nanorods into Standing SuperlatticesPd-CNT-SiO2 nanoskein: composite structure design for formic acid dehydrogenation
P50
Q31126780-6010D1C1-972E-4A65-955B-61ACF7D0E593Q34167765-E7FFCBB6-69D9-41D3-8E38-DFC8CA49B876Q35002891-502E13D9-F7D6-4ED9-AFB0-FF6BF24BBE49Q42928905-AE6DA4E1-4F80-446B-AB13-140E7CD43C53Q42935637-9239D2C9-CB4D-4687-AC5C-ADEA9CBBFC7CQ46283892-63DD7754-7D04-426D-9B37-5097A27AA579Q47137318-35F137D4-0501-494D-AD3C-DB97882A201DQ48151172-A30AEAD6-7AB9-4447-A75F-DC28608B3FE3Q50608890-D8B7DADB-A3FA-4D2A-9174-A22104BB45ABQ50803170-A6E067AF-9F54-444C-9799-91222E04B95AQ53444721-73704C36-BD90-4653-8656-8BCCD585D6E9Q57363806-525844AC-40EF-45DC-9538-5E50447B5C63Q60156795-85C33DEE-7DAE-448C-A270-0DC3156363CFQ60156802-E666A4E3-39CE-4788-B9D8-3E78E125D68AQ60156810-9E5C1BD2-7D5B-4813-AE2A-6B900EC02141Q62482567-D9B6989C-0B24-4FEE-8D6A-1D0FA28601AFQ62482603-01E27214-CFDA-4D2E-9551-F94C7D0C21B3Q62482641-523C4E98-94E7-46BC-AF85-A44D47D280A2Q62482648-4E61007D-93DF-4738-80DC-183A1048867CQ62552321-86B1ED35-EEA0-43A0-A1FD-C257F9F8800FQ92737723-6FEAF909-EE62-4C37-B4B3-7E21EE8B3F20
P50
description
researcher ORCID ID = 0000-0001-7472-9564
@en
wetenschapper
@nl
name
Enrique Carbó-Argibay
@ast
Enrique Carbó-Argibay
@en
Enrique Carbó-Argibay
@es
Enrique Carbó-Argibay
@nl
type
label
Enrique Carbó-Argibay
@ast
Enrique Carbó-Argibay
@en
Enrique Carbó-Argibay
@es
Enrique Carbó-Argibay
@nl
prefLabel
Enrique Carbó-Argibay
@ast
Enrique Carbó-Argibay
@en
Enrique Carbó-Argibay
@es
Enrique Carbó-Argibay
@nl
P106
P1153
23032977400
P21
P31
P496
0000-0001-7472-9564