A facile, sol−gel method to produce fluorescent, organically modified silica (ORMOSIL)−lanthanum phosphate (LaPO 4 ) hybrid nanocomposites suitable for gasphase CO 2 detection through a fluorescence-quenching mechanism is reported in the present work. ORMOSIL−LaPO 4 hybrid nanocomposites are prepared from a hybrid nanocomposite composition derived from trifunctional silanes such as methyltrimethoxysilane (MTMS), glycidoxypropyltrimethoxysilane (GPTMS), and from LaPO 4 nanorods, which act as fluorescent additives in the organically modified silane (ORMOSIL) matrix. Hybrid nanocomposite compositions containing MTMS and GPTMS were prepared in which the amount of LaPO 4 was varied. The wet alcogels thus obtained were dried under ambient conditions for 7 days, resulting in nanocomposite powders, and were calcined at 400 °C. The prepared nanocomposites were further characterized for their structural and functional features. The functional ORMOSIL matrix together with a luminescent additive like LaPO 4 makes the prepared ORMOSIL−LaPO 4 nanocomposite highly photoluminescent. The hybrid nanocomposite with nanoporous features exhibited a room-temperature CO 2 adsorption property and the photoluminescence intensity was found to quench with respect to CO 2 adsorption, which demonstrates the potential of the material to be used as a viable CO 2 sensor.
An increased discharge of nitrates to the natural water resources was observed across the globe due to various anthropogenic activities resulting in environmental pollution and associated harmful effects. In the present work, sol-gel-derived functional nanocomposites based on silver (Ag) doped titanium dioxide (TiO 2 ) coated chitosan nanocomposites were successfully synthesized in the form of beads and their application for the removal of nitrates from the water was studied. The synthesized nanocomposite beads were further characterized for their structural, textural, and morphological features using X-ray Diffraction Analysis, Fourier Transform Infrared Spectroscopy, UV-Visible Spectroscopy, BET Surface Area analysis, Scanning Electron Microscopy, and Transmission Electron Microscopy. A uniform coating of doped titania species on the chitosan porous structure was achieved through electrostatic interaction.Adsorption/ photocatalytic reduction of nitrates was further monitored by measuring the concentration of nitrate ions in the model contaminated water in the presence of functional nanocomposite beads when subjected to an adsorption study under dark conditions and photocatalytic study under UV/sunlight for a de nite time. Drying conditions of the nanocomposite beads were found to have a signi cant effect on the adsorption cum photocatalysis e ciencies of the nanocomposite. The freeze-dried chitosan-titania nanocomposite beads containing 0.5 mol% Ag exhibited an adsorption e ciency of ~ 43.5% (under dark for 30 min) and photocatalytic reduction capability of ~ 95% (under sunlight for 2 hours), whereas the adsorption and photocatalytic e ciencies were 40% (under dark for 30 min) and 70% (under UV light for 2 hours) respectively, in the case of oven-dried nanocomposite beads, towards the removal of nitrate ions in an aqueous solution. Continuous ow adsorption cum photocatalytic study using the oven-dried nanocomposite beads was carried out further with the help of an experimental setup fabricated in-house and under varying experimental conditions such as ow rate, bed height, and concentration of feed solution. A nitrate removal e ciency of 87.6% and an adsorption capacity of 7.9 mgg − 1 were obtained for the nanocomposite beads in the continuous ow adsorption cum photocatalysis experiment for up to 8 hours when using an inlet concentration of 100 ppm, bed height 12 cm and ow rate 5.0 mlmin − 1 . A representative xed-bed column adsorption experiment using a real groundwater sample collected from the Palakkad District of Kerala was also performed using the oven-dried functional nanocomposite beads that show promising results for nitrate removal (85.9% e ciency) along with a signi cant removal rate for the other anions as well. Thus, the adsorption cum photocatalytic nitrate reduction ability of the synthesized functional material makes them suitable for the e cient removal of nitrates from water/wastewater through an integrated nanocomposite approach.
An increased discharge of nitrates to the natural water resources was observed across the globe due to various anthropogenic activities resulting in environmental pollution and associated harmful effects. In the present work, sol-gel-derived functional nanocomposites based on silver (Ag) doped titanium dioxide (TiO 2 ) coated chitosan nanocomposites were successfully synthesized in the form of beads and their application for the removal of nitrates from the water was studied. The synthesized nanocomposite beads were further characterized for their structural, textural, and morphological features using X-ray Diffraction Analysis, Fourier Transform Infrared Spectroscopy, UV-Visible Spectroscopy, BET Surface Area analysis, Scanning Electron Microscopy, and Transmission Electron Microscopy. A uniform coating of doped titania species on the chitosan porous structure was achieved through electrostatic interaction.Adsorption/ photocatalytic reduction of nitrates was further monitored by measuring the concentration of nitrate ions in the model contaminated water in the presence of functional nanocomposite beads when subjected to an adsorption study under dark conditions and photocatalytic study under UV/sunlight for a de nite time. Drying conditions of the nanocomposite beads were found to have a signi cant effect on the adsorption cum photocatalysis e ciencies of the nanocomposite. The freeze-dried chitosan-titania nanocomposite beads containing 0.5 mol% Ag exhibited an adsorption e ciency of ~ 43.5% (under dark for 30 min) and photocatalytic reduction capability of ~ 95% (under sunlight for 2 hours), whereas the adsorption and photocatalytic e ciencies were 40% (under dark for 30 min) and 70% (under UV light for 2 hours) respectively, in the case of oven-dried nanocomposite beads, towards the removal of nitrate ions in an aqueous solution. Continuous ow adsorption cum photocatalytic study using the oven-dried nanocomposite beads was carried out further with the help of an experimental setup fabricated in-house and under varying experimental conditions such as ow rate, bed height, and concentration of feed solution. A nitrate removal e ciency of 87.6% and an adsorption capacity of 7.9 mgg − 1 were obtained for the nanocomposite beads in the continuous ow adsorption cum photocatalysis experiment for up to 8 hours when using an inlet concentration of 100 ppm, bed height 12 cm and ow rate 5.0 mlmin − 1 . A representative xed-bed column adsorption experiment using a real groundwater sample collected from the Palakkad District of Kerala was also performed using the oven-dried functional nanocomposite beads that show promising results for nitrate removal (85.9% e ciency) along with a signi cant removal rate for the other anions as well. Thus, the adsorption cum photocatalytic nitrate reduction ability of the synthesized functional material makes them suitable for the e cient removal of nitrates from water/wastewater through an integrated nanocomposite approach.
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