Photochemical activation is proposed as a general method for controlling the crystallization of sparingly soluble carbonates in space and time. The photogeneration of carbonate in an alkaline environment is achieved upon photo-decarboxylation of an organic precursor by using a conventional 365 nm UV LED. Local irradiation was conducted focusing the LED light on a 300 μm radius spot on a closed glass crystallization cell. The precursor solution was optimized to avoid the precipitation of the photoreaction organic byproducts and prevent photo-induced pH changes to achieve the formation of calcium carbonate only in the corresponding irradiated area. The crystallization was monitored in real-time by time-lapse imaging. The method is also shown to work in gels. Similarly, it was also shown to photo-activate locally the formation of barium carbonate biomorphs. In the last case, the morphology of these biomimetic structures was tuned by changing the irradiation intensity.

Menichetti A., Mavridi-Printezi Alexandra., Falini G., Besirske P., Garcia-Ruiz J.M., Colfen H., et al. (2021). Local Light-Controlled Generation of Calcium Carbonate and Barium Carbonate Biomorphs via Photochemical Stimulation. CHEMISTRY-A EUROPEAN JOURNAL, 27(49), 12521-12525 [10.1002/chem.202102321].

Local Light-Controlled Generation of Calcium Carbonate and Barium Carbonate Biomorphs via Photochemical Stimulation

Menichetti A.;Mavridi-Printezi Alexandra.;Falini G.;Montalti M.
2021

Abstract

Photochemical activation is proposed as a general method for controlling the crystallization of sparingly soluble carbonates in space and time. The photogeneration of carbonate in an alkaline environment is achieved upon photo-decarboxylation of an organic precursor by using a conventional 365 nm UV LED. Local irradiation was conducted focusing the LED light on a 300 μm radius spot on a closed glass crystallization cell. The precursor solution was optimized to avoid the precipitation of the photoreaction organic byproducts and prevent photo-induced pH changes to achieve the formation of calcium carbonate only in the corresponding irradiated area. The crystallization was monitored in real-time by time-lapse imaging. The method is also shown to work in gels. Similarly, it was also shown to photo-activate locally the formation of barium carbonate biomorphs. In the last case, the morphology of these biomimetic structures was tuned by changing the irradiation intensity.
2021
Menichetti A., Mavridi-Printezi Alexandra., Falini G., Besirske P., Garcia-Ruiz J.M., Colfen H., et al. (2021). Local Light-Controlled Generation of Calcium Carbonate and Barium Carbonate Biomorphs via Photochemical Stimulation. CHEMISTRY-A EUROPEAN JOURNAL, 27(49), 12521-12525 [10.1002/chem.202102321].
Menichetti A.; Mavridi-Printezi Alexandra.; Falini G.; Besirske P.; Garcia-Ruiz J.M.; Colfen H.; Montalti M.
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11585/833872
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