AI Article Synopsis
- The study investigates the self-assembly behavior of rigid amphiphiles comprising spherical Keggin clusters and rod-like oligofluorene blocks in varying solvent compositions of water and THF.
- Different solvent polarities allow the amphiphiles to form diverse structures, including incomplete onion-like layers, single-layered vesicles, and distinct macrophase separation.
- The rigid nature of the oligofluorene blocks affects the assembly process, leading to interdigitation and unique electrostatic interactions, thereby challenging the traditional packing parameter rules in self-assembly.
Article Abstract
We report complex macrophase and microphase transitions of rigid amphiphiles with spherical Keggin molecular clusters as the solvophilic block and rod-like rigid oligofluorene (OF) as the solvophobic block in mixed solvents of water and polar organic solvent. By properly adjusting the solvent polarity, the amphiphiles are found to respond accordingly by self-assembling into multilayered incomplete onion-like structures (10-25 vol % THF), single-layered vesicular structures (60 vol % THF), and an unexpected macrophase separation in the middle (40-50 vol % THF), which is due to the anomalous trends in Keggin solubility as a result of the nature of TBA counterions. The rigidity of the OF block prevents the amphiphile from assembling by following the rule of packing parameters; instead, interdigitation among different rods leads to the formation of the solvophobic domain to achieve self-assembly. The incomplete onion structures are controlled by the interdigitation of rigid rods for the number of layers and the electrostatic interaction among Keggin head groups for the interlayer distance. When the degree of interdigitation becomes lower, the self-assembly process shows a trend that can be explained by the traditional rule of packing parameter. This study demonstrates the formation of different self-assembled structures by rigid amphiphiles and their transitions induced by solvent composition. The self-assembly (microphase separation) of rigid amphiphiles in a dilute solution could indeed represent a broad area containing complicated, uncharted rules.
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| http://dx.doi.org/10.1021/acsami.4c10543 | DOI Listing |
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