Calcite mesocrystals: a very effective block polyelectrolyte for crystal "Morphing"(<Feature>Aqueous Solution Science for Ceramic Processing II)
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概要
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A family of calcite nanocrystal superstructures with unusual morphology were obtained from crystallization of calcite by the CO_2 gas diffusion technique in the presence of a bioinspired double hydrophilic block copolymer, polyethyleneglycol-block-poly (L-aspartic acid). From the typical calcite rhombohedra as a starting situation, the morphology can be systematically varied via various unusual porous mesocrystal morphologies to hemispheres composed of fine calcite triangles. The formation of mesocrystals is starting at a polymer concentration of only 10^<-3>g/L and shows two remarkable results: (a) the reported bio-inspired block copolymer is the so far most active polymer for mesocrystal formation reported to our knowledge, and (b) the data prove that nucleation promoters exist, which can form nanocrystals for mesocrystal formation even without enhanced colloidal stabilization. This gives mesocrystal formation a much broader operation range than previously assumed.
- 2009-03-01
著者
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Antonietti Markus
Max-planck-institute Of Colloids And Interfaces Department Of Colloid Chemistry Research Campus Golm
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Borner Hans
Max-planck-institute Of Colloids And Interfaces Department Of Colloid Chemistry Research Campus Golm
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WANG Tongxin
Max-Planck-Institute of Colloids and Interfaces, Department of Colloid Chemistry, Research Campus Go
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VERCH Andreas
Max-Planck-Institute of Colloids and Interfaces, Department of Colloid Chemistry, Research Campus Go
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COLFEN Helmut
Max-Planck-Institute of Colloids and Interfaces, Department of Colloid Chemistry, Research Campus Go
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Wang Tongxin
Max-planck-institute Of Colloids And Interfaces Department Of Colloid Chemistry Research Campus Golm
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Verch Andreas
Max-planck-institute Of Colloids And Interfaces Department Of Colloid Chemistry Research Campus Golm
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Colfen Helmut
Max-planck-institute Of Colloids And Interfaces Department Of Colloid Chemistry Research Campus Golm