Dye Modification of Nanofibrous Silicon Oxide Membranes for Colorimetric HCl and NH<sub>3</sub> Sensing

Geltmeyer, Jozefien; Vancoillie, Gertjan; Steyaert, Iline; Breyne, Bet; Cousins, Gabriella; Lava, Kathleen; Hoogenboom, Richard; Buysser, Klaartje De; Clerck, Karen De

doi:10.1002/adfm.201602351

Cited by 65 publications

(43 citation statements)

References 49 publications

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“…When stored at room temperature (RT, 20 °C) and 65% relative humidity (RH), the hydrophobic/hydrophilic switch is observed after 4 months (right region of Figure ). In the case of an RH of 90%, the membrane is superhydrophilic within 21 d . The lower the relative humidity, the longer the hydrophobic nature lasts.…”

Section: Resultsmentioning

confidence: 99%

Silica Nanofibrous Membranes for the Separation of Heterogeneous Azeotropes

Loccufier

Geltmeyer

Daelemans

et al. 2018

Adv Funct Materials

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Nanofibrous materials produced through electrospinning are characterized by a high porosity, large specific surface area, and high pore interconnectivity and, therefore, show potential for, e.g., separation and filtration. The development of more inert nanofibers with higher thermal and chemical resistance extends the application field to high-end purification. Silica nanofibrous membranes produced by direct electrospinning of a sol-gel solution without a sacrificing carrier, starting from tetraethoxysilane, meet these challenging requirements. After electrospinning the membrane is highly hydrophobic. Storage under dry conditions preserves this property. Oppositely, a superhydrophilic membrane is obtained by storage under high humidity (month scale). This switch is caused by the reaction of ethoxy groups, present due to incomplete hydrolysis of the precursor, with moisture in the air, resulting in an increased amount of silanol groups. This transition can be accelerated to hour scale by applying a heat treatment, with the additional increase in cross-linking density for temperatures above 400 °C, enabling applications that make use of hydrophobic and hydrophilic membranes by tuning the functionalization. It is showcased that upon designing the water repellent or absorbing nature of the silica material, fast gravity-driven membrane separation of heterogeneous azeotropes can be achieved.

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Section: Resultsmentioning

confidence: 99%

Silica Nanofibrous Membranes for the Separation of Heterogeneous Azeotropes

Loccufier

Geltmeyer

Daelemans

et al. 2018

Adv Funct Materials

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“…The silica nanofibers can change their hydrophilicity in time [31]. Therefore, both hydrophobic and hydrophilic samples were dip-coated, which resulted in a significant difference in TiO2 loading (Figure 2 f,g and Table 1).…”

Section: Characterization Of Tio2 Functionalized Membranesmentioning

confidence: 99%

TiO2 functionalized nanofibrous membranes for removal of organic (micro)pollutants from water

Geltmeyer

Teixido

Meire

et al. 2017

Separation and Purification Technology

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Abbreviations 1 1 PA 6: polyamide 6, MB: Methylene Blue, IL: inline, DC: dip-coating, H: hydrophilic 2 ABSTRACT Titania has already proven its added value for air and water treatment. The higher the surface-to-volume area, the better the performance of the TiO2 photocatalyst. These nanoparticles are typically applied in a slurry form. The use of titania nanoparticles in suspension has, however, multiple disadvantages such as a high turbidity and complex recovery of the photocatalyst after use. Therefore, immobilization of titania nanoparticles on a porous support such as a nanofibrous membrane, can be highly valuable for water treatment. These TiO2 functionalized nanofibrous membranes may be used not only in a membrane separation reactor, but also in a contact reactor. In this study, TiO2 nanoparticles were immobilized on both polymer (polyamide 6) and ceramic (silica) nanofibrous membranes. Polymer nanofibers are chosen as they are the state-of-the-art material, silica nanofibers on the contrary are less studied but show additional advantages due their excellent chemical and thermal stability and can thus offer a clear benefit for a wider range of applications. Two immobilization techniques were used, namely inline functionalization and dip-coating. Inline functionalization showed to be the preferred method for polyamide 6 nanofibrous membranes, dip-coating for silica nanofibrous membranes. Complete degradation of isoproturon, an actual concern in water treatment, is shown. Even the widely available commercial TiO2 nanoparticles allowed for a complete isoproturon removal as the result of a correct immobilization process on nanofibrous materials. This clearly opens up the high value of TiO2 functionalized nanofibrous membranes for organic (micro)pollutants removal.

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“…Therefore, it is beneficial to not restrict colorimetric sensor design to organic polymers, but broaden their applicability by producing sensors from ceramic nanofibers. By combining stimuli‐sensitive dyes, the advantageous properties of nanofibers and the high temperature and chemical resistance of ceramic sol‐gel based materials, we designed an advanced colorimetric sensor with a unique combination of properties based on dye‐doping of silica nanofibers . In contrast to the usually non‐flexible bulk glass or thin film sensors, our designed large‐area ceramic nanofibrous sensors were flexible.…”

Section: Colorimetric Sensors Based On Doped Nanofibersmentioning

confidence: 99%

Section: Colorimetric Sensors Based On Doped Nanofibersmentioning

confidence: 99%

Colorimetric Nanofibers as Optical Sensors

Schoolaert

Hoogenboom

Clerck

2017

Adv Funct Materials

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110

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Sensors play a major role in many applications today, ranging from biomedicine to safety equipment, where they detect and warn us about changes in the environment. Nanofibers, characterized by high porosity, flexibility, and a large specific surface area, are the ideal material for ultrasensitive, fastresponding, and user-friendly sensor design. Indeed, a large specific surface area increases the sensitivity and response time of the sensor as the contact area with the analyte is enlarged. Thanks to the flexibility of membranes, nanofibrous sensors cannot only be applied in high-end analyte detection, but also in personal, daily use. Many different nanofibrous sensors have already been designed; albeit, the most straightforward and easiest-to-interpret sensor response is a visual change in color, which is of particular interest in the case of warning signals. Recently, many researchers have focused on the design of so-called colorimetric nanofibers, which typically involve the incorporation of a colorimetric functionality into the nanofibrous matrix. Many different strategies have been used and explored for colorimetric nanofibrous sensor design, which are outlined in this feature article. The many examples and applications demonstrate the value of colorimetric nanofibers for advanced optical sensor design, and could provide directions for future research in this area.

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Dye Modification of Nanofibrous Silicon Oxide Membranes for Colorimetric HCl and NH₃ Sensing

Cited by 65 publications

References 49 publications

Silica Nanofibrous Membranes for the Separation of Heterogeneous Azeotropes

Silica Nanofibrous Membranes for the Separation of Heterogeneous Azeotropes

TiO2 functionalized nanofibrous membranes for removal of organic (micro)pollutants from water

Colorimetric Nanofibers as Optical Sensors

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Dye Modification of Nanofibrous Silicon Oxide Membranes for Colorimetric HCl and NH3 Sensing

Cited by 65 publications

References 49 publications

Silica Nanofibrous Membranes for the Separation of Heterogeneous Azeotropes

Silica Nanofibrous Membranes for the Separation of Heterogeneous Azeotropes

TiO2 functionalized nanofibrous membranes for removal of organic (micro)pollutants from water

Colorimetric Nanofibers as Optical Sensors

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Product

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Dye Modification of Nanofibrous Silicon Oxide Membranes for Colorimetric HCl and NH₃ Sensing