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Monolithic gyroidal mesoporous mixed titanium-niobium nitridesImmobilization of nanobeads on a surface to control the size, shape and distribution of pores in electrochemically generated sol-gel films.Modification of Charge Trapping at Particle/Particle Interfaces by Electrochemical Hydrogen Doping of Nanocrystalline TiO2.Fabrication of magneto-controlled moveable architecture to develop reusable electrochemical biosensors.Hybrid and biohybrid layered double hydroxides for electrochemical analysis.Hybrid materials science: a promised land for the integrative design of multifunctional materials.Block copolymer-derived monolithic polymer films and membranes comprising self-organized cylindrical nanopores for chemical sensing and separations.Vertically ordered silica mesochannel films: electrochemistry and analytical applications.3D graphene-based hybrid materials: synthesis and applications in energy storage and conversion.Structure and Modification of Electrode Materials for Protein Electrochemistry.Recent Trends on Electrochemical Sensors Based on Ordered Mesoporous Carbon.Facile control of long range orientation in mesoporous carbon films with thermal zone annealing velocity.Tunable hierarchical macro/mesoporous gold microwires fabricated by dual-templating and dealloying processes.Co(2+)@Mesoporous Silica Monoliths: Tailor-Made Nanoreactors for Confined Soft Chemistry.Differential pulse voltammetry detection of dopamine and ascorbic acid by permselective silica mesochannels vertically attached to the electrode surface.Electrochemically assisted self-assembly of ordered and functionalized mesoporous silica films: impact of the electrode geometry and size on film formation and properties.Reversible control of pore size and surface chemistry of mesoporous silica through dynamic covalent chemistry: philicity mediated catalysis.The Development of Functional Mesocrystals for Energy Harvesting, Storage, and Conversion.Complex Nanostructures from Materials based on Metal-Organic Frameworks for Electrochemical Energy Storage and Conversion.Mesoporous Semimetallic Conductors: Structural and Electronic Properties of Cobalt Phosphide Systems.Surfactant-free synthesis of three-dimensional nitrogen-doped hierarchically porous carbon and its application as an electrode modification material for simultaneous sensing of ascorbic acid, dopamine and uric acid.Raspberry-Like Bismuth Oxychloride on Mesoporous Siliceous Support for Sensitive Electrochemical Stripping Analysis of Cadmium.Highly Ordered Mesostructured Vanadium Phosphonate toward Electrode Materials for Lithium-Ion Batteries.A new strategy for synthesis of porous magnetic supraparticles with excellent biodegradability.Enzymatic Biofuel Cells on Porous Nanostructures.Electrospun manganese-cobalt oxide hollow nanofibres synthesized via combustion reactions and their lithium storage performance.Interfacial processes studied by coupling electrochemistry at the polarised liquid-liquid interface with in situ confocal Raman spectroscopy.Three-dimensionally ordered macro-/mesoporous Ni as a highly efficient electrocatalyst for the hydrogen evolution reactionMesoscale organization of titania thin films enables oxygen sensing at room temperatureRecent advances in ordered meso/macroporous metal oxides for heterogeneous catalysis: a reviewGraphene-based materials for capacitive deionizationKinetically Controlled Synthesis of PdNi Bimetallic Porous Nanostructures with Enhanced Electrocatalytic ActivityElectrocatalytic Oxidation and Determination of Cysteine at Oxovanadium(IV) Salen Coated Electrodes
P2860
Q34104291-6F555719-E1FA-4FC1-BC0D-1D350DE57BC6Q35831778-2BE267A3-9A7B-4431-BDBF-1CE87FD2159DQ37541056-7CD47355-FA91-4DDB-B638-53CA5BFE0736Q37601605-4D35A98A-C220-4305-88AA-B3114C6B83D4Q38083581-301A9F1A-037F-4458-B834-649B7CBD6C84Q38215333-29929CF6-D095-41B8-820F-89B44F3A7B5CQ38218581-F4A8BA85-959E-4CBE-AEA7-D93057668D0BQ38764835-4868C8C4-DACD-4C98-A50C-8486ECCDE150Q38830676-428F6F14-AAD2-46D8-BE3A-406071DD255CQ38923180-ACC04D40-46B3-4005-8758-2EDFF43CF33FQ41583666-4508C30A-57DF-4EE1-916A-1257C50F65EAQ44898675-A617CE43-A8AC-4455-8E3C-8E21102106A0Q46095315-5068CD26-2AAA-4176-B916-5D343D160A18Q46660742-53FE7EC2-D6CA-4711-A46B-BDFC40682468Q46876625-DB0FED6C-B18D-442D-AC10-AA1417F80E3EQ46940747-8D1EA8C1-E9D1-4907-A1CD-4A0304C2EA6FQ47377792-0801C117-1CC9-4DC2-B534-0825F32623DFQ47427241-D62381E2-3A3B-4828-A29C-463AFF591E60Q47619992-4CBA0E9E-F337-4B68-9BC8-5806BC154A92Q47642983-39CD32AA-0901-42B2-B01B-065C70BA32B0Q48347442-FFDE2F25-BA8A-4CD2-BFA2-2F0BD1117701Q50875069-A8606D2F-775E-478E-BEB6-D3C9AA883F15Q50974840-92A43AF7-ED5A-43AC-9CA0-204616C9DE9CQ51023068-CC147220-5192-4862-89D4-884EF5CA0EFBQ53073292-C2F308BB-FF55-41E3-B2E1-FB6CBC0D5579Q53535392-99689048-8855-4AEE-86B5-363C2CD16DF0Q54224075-82D0ECEE-FDCA-4DDC-9BD1-DE54DF86063DQ57536056-943BA435-EE8A-4B12-B6EE-B9F7EE59334CQ57578097-7BD0B080-EE38-46EE-8119-0431818A9C8EQ57823415-959105EB-044D-4B93-8BDA-83456B65CDDAQ58351474-A546A984-4686-49EC-8D22-63B55D2DCA2FQ58371832-8A2ABB31-8FD4-46E7-B0EC-4CF6A2741F6EQ59043721-6C5EFD80-D734-49A3-A0D8-5B64B9AB240E
P2860
description
article científic
@ca
article scientifique
@fr
articol științific
@ro
articolo scientifico
@it
artigo científico
@gl
artigo científico
@pt
artigo científico
@pt-br
artikel ilmiah
@id
artikull shkencor
@sq
artículo científico
@es
name
Mesoporous materials and electrochemistry.
@en
type
label
Mesoporous materials and electrochemistry.
@en
prefLabel
Mesoporous materials and electrochemistry.
@en
P356
P1476
Mesoporous materials and electrochemistry.
@en
P2093
Alain Walcarius
P304
P356
10.1039/C2CS35322A
P577
2013-01-18T00:00:00Z