We detected local pH changes in real time during formation of inorganic self-assembled systems by wide field and confocal fluorescence microscopy. The aim was to identify and characterize fluorescent probes that can work in specific pH ranges in peculiar conditions, such as presence of concentrated metal ions. We had also to re-design the crystallization setup reported in literature to make it compatible with the observation in fluorescence microscopy. Three kinds of systems have been studied, for which different specific experimental approaches have been developed: calcium biomorphs in silica gel that form calcite and aragonite stripes, barium biomorphs in silica gel, and silica gardens. A ratiometric method for mapping pH in silica gel-grown biomorphs during diffusion of calcium and barium was developed, so that it was possible to correlate the morphogenetic process to the local pH changes. We concluded that biomorphs formation starts at very specific pH values and their growth occurs in a pH gradient in a diffusional regime. Differently from sol-grown biomorphs, any localized and oscillating changes of pH in proximity of the front of growth of the biomorphs were not detected. This result suggests that the properties of the matrix (e.g. silica sol vs. gel, thickness) are very critical in determining possible accumulation of chemical species around biomorphic structures. About silica gardens, we could observe locally and in real time precipitation/re-dissolution processes, resulting from diffusion of chemical species through the membrane formed at the interface between metal and silicate solutions, which were analyzed in detail and whose possible chemical mechanisms were proposed. Thanks to fluorescence based pH mapping of growing silica gardens in a quasi 2D regime, the tubular membrane growth was for the first time demonstrated to involve formation of jet (even in the absence of buoyancy) where actual mixing of the metal and silicate solutions occurs.
Mapping pH in self-assembled inorganic structures by fluorescence micriscopy
2018
Abstract
We detected local pH changes in real time during formation of inorganic self-assembled systems by wide field and confocal fluorescence microscopy. The aim was to identify and characterize fluorescent probes that can work in specific pH ranges in peculiar conditions, such as presence of concentrated metal ions. We had also to re-design the crystallization setup reported in literature to make it compatible with the observation in fluorescence microscopy. Three kinds of systems have been studied, for which different specific experimental approaches have been developed: calcium biomorphs in silica gel that form calcite and aragonite stripes, barium biomorphs in silica gel, and silica gardens. A ratiometric method for mapping pH in silica gel-grown biomorphs during diffusion of calcium and barium was developed, so that it was possible to correlate the morphogenetic process to the local pH changes. We concluded that biomorphs formation starts at very specific pH values and their growth occurs in a pH gradient in a diffusional regime. Differently from sol-grown biomorphs, any localized and oscillating changes of pH in proximity of the front of growth of the biomorphs were not detected. This result suggests that the properties of the matrix (e.g. silica sol vs. gel, thickness) are very critical in determining possible accumulation of chemical species around biomorphic structures. About silica gardens, we could observe locally and in real time precipitation/re-dissolution processes, resulting from diffusion of chemical species through the membrane formed at the interface between metal and silicate solutions, which were analyzed in detail and whose possible chemical mechanisms were proposed. Thanks to fluorescence based pH mapping of growing silica gardens in a quasi 2D regime, the tubular membrane growth was for the first time demonstrated to involve formation of jet (even in the absence of buoyancy) where actual mixing of the metal and silicate solutions occurs.File | Dimensione | Formato | |
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https://hdl.handle.net/20.500.14242/144382
URN:NBN:IT:UNIBO-144382