AI Article Synopsis
- Silica nanoflakes and nanospheres with unique pore structures show promise for various applications, with their formation involving a chiral amphiphile called L-18Ala4PyBr.
- Different versions of the amphiphile, L-18Ala6PyBr and L-18Ala11PyBr, were created by changing the length of the bridging alkylene chain, leading to the production of distinct silica structures.
- The study suggests that the way these alkylene chains group together significantly influences the shapes and pore designs of the resulting mesoporous silica materials.
Article Abstract
Silica nanoflakes and nanospheres with perpendicular pore channels are attractive due to their potential applications. Herein, the nanoflakes were prepared using the self-assemblies of a chiral low-molecular-weight amphiphile, L-18Ala4PyBr, as the templates; and nanospheres were prepared using this amphiphile and cyclohexane as a co-structure-directing agent. By gradually increasing the bridging alkylene chain length of L-18Ala4PyBr, amphiphiles L-18Ala6PyBr and L-18Ala11PyBr were synthesized. Nanoflakes with perpendicular pore channels and nanoworms with horizontal pore channels were prepared using L-18Ala6PyBr and L-18Ala11PyBr, respectively. The hydrophobic association of the bridging alkylene chains should play an important role in controlling the morphologies and pore architectures of the mesoporous silicas.
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| http://dx.doi.org/10.1166/jnn.2012.5178 | DOI Listing |
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