Ethanol–water co-condensation into hydrophobic mesoporous thin films: example of a photonic ethanol vapor sensor in humid environment

In this work, we report a new generation of sol–gel photonic vapor sensor based on water-repellent methyl-functionalized mesoporous silica thin films for the detection of alcohol vapors. Relative humidity, generally accountable for sensor performance deterioration, was demonstrated as a key paramete...

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Bibliographic Details
Published in:Journal of sol-gel science and technology 2017, Vol.81 (1), p.95-104
Main Authors: Boudot, Mickael, Cattoni, Andrea, Grosso, David, Faustini, Marco
Format: Article
Language:English
Subjects:
Adsorption
Alcohol
Analytical chemistry
Capillary pressure
Ceramics
Chemical Sciences
Chemistry and Materials Science
Composites
Condensation
Ellipsometry
Ethanol
Glass
Gratings (spectra)
Humidity
Hydrophobicity
Inorganic Chemistry
Magnetic amplifiers
Material chemistry
Materials Science
Nanotechnology
Natural Materials
Optical and Electronic Materials
Optical communication
Original Paper: Sol-gel and hybrid materials for catalytic
Parameter sensitivity
Performance degradation
photoelectrochemical and sensor applications
Photonics
Porous materials
Refractivity
Regeneration
Relative humidity
Sensitivity enhancement
Sensors
Silicon dioxide
Sol-gel processes
Surface energy
Surfactants
Thin films
Vapor pressure
Water pressure
Water vapor
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Summary:In this work, we report a new generation of sol–gel photonic vapor sensor based on water-repellent methyl-functionalized mesoporous silica thin films for the detection of alcohol vapors. Relative humidity, generally accountable for sensor performance deterioration, was demonstrated as a key parameter to detect and enhance sensor sensitivity concerning ethanol. The ethanol-assisted water vapor capillary condensation into hydrophobic mesopores was observed and investigated as an innovative sensing mechanism. We showed that water condensation was triggered by the surfactant-like behavior of alcohol molecules whose alkyl moieties preferentially interact with the hydrophobic walls and reversibly switch the surface energy from hydrophobic to hydrophilic. Influence of the ethanol and water pressure conditions for which the capillary condensation occurs were studied by in situ ellipsometry. This study revealed a synergic mechanism of co-adsorption where the minimum ethanol concentration allowing water capillary adsorption decreases when humidity increases. Nanopatterned diffraction gratings films, fabricated via a nanoimprinting process, were demonstrated to be efficient transductor to transform the capillary-induced nanoscale variations of refractive index of the porous materials into optical signals easily measurable by conventional camera. Sensing results exhibited an ethanol vapor pressure threshold limit of detection of P / P 0 EtOH  = 0.07 at 100 % relative humidity and typical response and regeneration times are below one minute. Graphical Abstract
ISSN:0928-0707
1573-4846
DOI:10.1007/s10971-016-4084-2