2015
DOI: 10.1039/c4ta04844j
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Positioning growth of scalable silica nanorods on the interior and exterior surfaces of porous composites

Abstract: A novel yet straightforward one-pot synthesis technique was developed to grow silica nanorods on the interior and exterior surfaces of a porous, inorganic scaffold. Growth of the rods on the surface, versus in the bulk, was achieved by functionalizing the surface with chlorosilane molecules, which allowed the emulsion droplets in which the nanorods grow to anchor to the surface. Rods of 100-200 nm diameter and up to 2 mm in length could be grown uniformly over the surface with a typical surface density of 3 ro… Show more

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Cited by 12 publications
(23 citation statements)
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“…The longer the rods were, the better the flexural strength was. Rod growth on the interior and exterior surfaces of kaolinite–silica porous composites has also been achieved . Control of reaction parameters achieves control of the size, shape, and surface density of the rods.…”
Section: Applicationsmentioning
confidence: 99%
See 1 more Smart Citation
“…The longer the rods were, the better the flexural strength was. Rod growth on the interior and exterior surfaces of kaolinite–silica porous composites has also been achieved . Control of reaction parameters achieves control of the size, shape, and surface density of the rods.…”
Section: Applicationsmentioning
confidence: 99%
“…Following the same strategy, silica rods on gold cubes and smooth surfaces have been grown, which led to sea‐urchin‐type structures . The rods were also grown in and outside of porous composites …”
Section: Rod Growth On Other Surfacesmentioning
confidence: 99%
“…As the thickness of the gel fibers can be tuned by changingt he concentration of the gelator,t his methodology may be useful to make porousp olystyrenes with tunable pore diameters. Silica microstructures are of great interestf or variousa pplications, such as hydrophobic coating, [20] composite materials, [21] light scatterers in solar cells, [22] biomedical fields, [23] separation, [24] and so on. [25] Shinkai et al used organogels derived from cholesterol as templates for the polymerization of TEOS to produce variousn anostructured silica architectures, including ribbons, helices, rods, and tubes.…”
Section: Resultsmentioning
confidence: 99%
“…MSPs can be synthesized using a template (surfactants) and silica precursors (tetraethyl ortosilicate, TEOS and tetramethyl ortosilicate, TMOS). Depending on the synthesis conditions, (e.g., type of surfactant, ionic strength, pH, additives, temperature, and reaction time) different porous structures and morphologies could be obtained such as MCM-X, MSU-X, and SBA families (Giraldo et al 2007;Huang et al 2011;Li et al 2015;Showkat et al 2007;Zhang et al 2007). The silica/polymer nanocomposites have been prepared using electrospinning method because the silica part can improve the toughness, durability, and permeability of polymeric nanofibers (Ji et al 2008;Shi et al 2011).…”
Section: Introductionmentioning
confidence: 99%