Unravelling the structural hierarchy in microemulsion droplet templated dendritic fibrous nano silica

Abstract Microemulsion-templated dendritic fibrous nanosilica (DFNS) has attracted considerable attention owing to their unique accessible pore structure and high-surface-area but their complex structural hierarchy is still intriguing. In this work, a correlative quantification of the hierarchical structure of such nanospheres has been presented based upon three complementary techniques; small-angle scattering, gas sorption, and electron microscopy. Analysis of scattering data over a wide range of wave-vector transfer using polydisperse Teubner Strey model reveals three distinct levels of correlated bicontinuous morphology and the pore-size distribution from N2 gas sorption resembles well with the results obtained from scattering analysis. The formation mechanism of such hierarchical pore morphology in these nanospheres is elucidated and it is observed that a relative variation in periodicity, sheet thickness, and their correlation significantly affects the specific surface area and pore structure, which is strongly influenced by hydrolysis rate and reaction time.