Search results for "Functional devices"

showing 2 items of 2 documents

Optical Gating of Photosensitive Synthetic Ion Channels

2011

4-oxo-4-(pyren-4-ylmethoxy) butanoic acid is used as a photolabile protecting group to show the optical gating of nanofluidic devices based on synthetic ion channels. The inner surface of the channels is decorated with monolayers of photolabile hydrophobic molecules that can be removed by irradiation, which leads to the generation of hydrophilic groups. This process can be exploited in the UV-light-triggered permselective transport of ionic species in aqueous solution through the channels. The optical gating of a single conical nanochannel and multichannel polymeric membranes is characterised experimentally and theoretically by means of current-voltage and selective permeation measurements,…

Hydrophilic groupsMaterials scienceSynthetic ion channelsLight sensitive materialsHydrophobicitySynthetic membraneNanotechnologyNano-fluidic devicesGatingIonIonic transportsBiomaterialsPolymeric membranesOptical gatingPhotosensitivityOptical gatingsSynthetic ion channelsMonolayerElectrochemistryControlled releasePhotolabile protecting groupsIonic speciesPolymer membranesHydrophobic moleculesFunctional polymersSelective permeationHydrophilicityMultifunctional devicesMonolayersIonsAqueous solutionCurrent rectificationUV-light irradiationMulti-channelPermeationCondensed Matter PhysicsNanostructuresElectronic Optical and Magnetic MaterialsData processingPhotosensitive nanostructuresFISICA APLICADAIrradiationNano channelsInner surfacesFunctional polymersCurrent voltageAdvanced Functional Materials
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Relative Humidity Dependent Resistance Switching of Bi2S3Nanowires

2017

Electrical properties of Bi2S3nanowires grown using a single source precursor in anodic aluminum oxide templates are sensitive to the relative humidity in an inert gas environment. Dynamic sensing dependency is obtained and shows presence of spontaneous resistance switching effect between low and high relative humidity states. Employing the thermionic field emission theory, heights of Schottky barriers are estimated from the current-voltage characteristics and in relation to the humidity response. The change of Schottky barrier height is explained by local changes in physically adsorbed water molecules on the surface of the nanowire.

Materials scienceArticle SubjectSchottky barrierNanowireSemiconductor nanowiresBi2S3 nanowires02 engineering and technologyFunctional devices010402 general chemistry01 natural sciencesAdsorptionlcsh:Technology (General)MoleculeGeneral Materials ScienceRelative humidityInert gasNanowiresfood and beveragesHumiditySchottky diode021001 nanoscience & nanotechnologyhumanitiesDynamic sensing dependencySchottky barriers0104 chemical sciencesChemical physicslcsh:T1-9950210 nano-technologyJournal of Nanomaterials
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