about
High performing solution-coated electrolyte-gated organic field-effect transistors for aqueous media operation.Self-assembled monolayers in organic electronics.The Substrate is a pH-Controlled Second Gate of Electrolyte-Gated Organic Field-Effect Transistor.Electrowetting of nitro-functionalized oligoarylene thiols self-assembled on polycrystalline gold.Electrical release of dopamine and levodopa mediated by amphiphilic β-cyclodextrins immobilized on polycrystalline gold.Electron transfer and electrocatalytic properties of the immobilized methionine80alanine cytochrome c variant.Fluid Mixing for Low-Power 'Digital Microfluidics' Using Electroactive Molecular Monolayers.Biorecognition in Organic Field Effect Transistors Biosensors: The Role of the Density of States of the Organic Semiconductor.Multiscale sensing of antibody-antigen interactions by organic transistors and single-molecule force spectroscopy.Electrolyte-Gated Organic Field-Effect Transistor Based on a Solution Sheared Organic Semiconductor Blend.Self-assembly of mono- and bidentate oligoarylene thiols onto polycrystalline AuTailoring water stability of cellulose nanopaper by surface functionalizationModification of the gate electrode by self-assembled monolayers in flexible electrolyte-gated organic field effect transistors: work function vs. capacitance effectsCharge-Injection Organic Gauges to Detect Dopamine Down to the Nanomolar ScaleHydrophilic self-assembly monolayers for pentacene-based thin-film transistorsOrganic field-effect transistor for label-free dopamine sensingWater-gated organic field effect transistors – opportunities for biochemical sensing and extracellular signal transductionDouble layer capacitance measured by organic field effect transistor operated in waterMono/bidentate thiol oligoarylene-based self-assembled monolayers (SAMs) for interface engineeringOrganic field-effect transistors as new paradigm for large-area molecular junctionsSurface Immobilized His-tagged Azurin as a Model Interface for the Investigation of Vectorial Electron Transfer in Biological SystemsMorphological and mechanical properties of alkanethiol self-assembled monolayers investigated via bimodal atomic force microscopyCatalytic reduction of dioxygen and nitrite ion at a Met80Ala cytochrome c-functionalized electrodeElectron transfer properties and hydrogen peroxide electrocatalysis of cytochrome c variants at positions 67 and 80
P50
Q36231065-F6159091-2CE6-48B5-92F5-D258D150484CQ38976893-36C7DA28-7EAC-450D-9E1E-2BDF88F938D5Q39366731-769CCB38-8DCC-4C20-BFD5-AA047F8E3728Q40254475-A5F301F8-7395-4436-8494-2A3C78E7D3C5Q46639796-E62F5959-88D1-4EB8-A043-81DD5FB88B72Q46809170-286F07EF-9615-42A3-B665-6715792B319BQ47216933-5B43A832-64A3-4B46-858F-2096CAABD612Q48047398-19B0A1B6-FA48-4495-B762-A2BFAC26D8DCQ50989880-55A8419E-96EB-42C5-BEEA-6F8C7285D9CFQ52886552-FE6394AD-F3F1-4B84-B120-318D3CF40E8CQ56977075-DD68B33E-70EB-4D6F-B736-B83F61120B04Q57131020-E3DDA660-6991-484C-9A2F-8B05294D4003Q58237056-115B2E6A-D909-44A9-A327-99FD04044C18Q58237058-C6AC2B4A-E349-4974-B6E8-4EA3532AABD0Q58237060-97A8FAD7-11A6-459A-8319-7964FC8253C6Q58237062-DC0E33BF-D0BD-454C-BC76-A4923014A790Q58237065-E656B2F7-DE95-40A4-AB21-7A8116D71B37Q58237066-1488B06C-8984-43D2-8A14-16A40DD10B5CQ58237068-1D83A25B-EF11-4E96-8CB4-5C1DC43AB08FQ58237069-05BC57AE-8368-413B-A017-2D2941609DE6Q61700304-FD03E04E-E344-477A-8E8E-C72EDBF1CE41Q61716082-90BB525B-2609-491B-ADA3-A08A78752684Q82298422-4C924B05-1ACA-4C93-A220-EC34B0921F47Q82440648-9A1F7045-4584-4E47-9126-71DF516D74AD
P50
description
hulumtues
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researcher
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wetenschapper
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հետազոտող
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name
Stefano Casalini
@ast
Stefano Casalini
@en
Stefano Casalini
@es
Stefano Casalini
@nl
Stefano Casalini
@sl
type
label
Stefano Casalini
@ast
Stefano Casalini
@en
Stefano Casalini
@es
Stefano Casalini
@nl
Stefano Casalini
@sl
prefLabel
Stefano Casalini
@ast
Stefano Casalini
@en
Stefano Casalini
@es
Stefano Casalini
@nl
Stefano Casalini
@sl
P1053
J-4299-2012
P106
P21
P31
P3829
P496
0000-0003-3609-1154