Formation pathways of mesoporous silica nanoparticles with dodecagonal tiling

Sun, Yao; Ma, Kai; Kao, Teresa; Spoth, Katherine A.; Sai, Hiroaki; Zhang, Duhan; Kourkoutis, Lena F.; Elser, Veit; Wiesner, Ulrich

doi:10.1038/s41467-017-00351-8

Cited by 69 publications

(57 citation statements)

References 38 publications

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“…We recently demonstrated that increased size dispersion in surfactant micelle systems with added pore expander (i.e., oil phase) favors the formation of cage‐like mesoporous silica with nonuniform cage structures rationalizing the appearance of the clathrate IV structure at twice the ammonium hydroxide concentration (vide supra). [ 9 ] In order to increase the micelle size dispersion and further bias the system toward such structures, we mixed two surfactants of different chain lengths (C 16 TAB and C 8 TAB, see Experimental Section). In conjunction with a 1.5‐fold increase of the amount of ammonium hydroxide relative to single‐layer conditions to promote multilayer growth, this indeed resulted in superstructures showing exclusively the clathrate IV structure (Figure 3d−f).…”

Section: Figurementioning

confidence: 99%

“…Since the early reports on directed silica self‐assembly, [ 1 ] these materials and their derivatives in the bulk, [ 2,3 ] as films, [ 4 ] and as nanoparticles [ 5,6 ] have been the subject of extensive research efforts. Benign synthesis conditions, often in aqueous solutions at room temperature, concomitant low toxicity and favorable biocompatibility, [ 7 ] continuous structure discovery, [ 8–10 ] as well as their application potential across different areas, e.g. in catalysis, [ 11 ] energy, [ 12 ] and nanomedicine, [ 6,13 ] maintain high academic and industrial interest levels.…”

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confidence: 99%

“…[ 16 ] In the presence of cationic surfactants such as cetyltrimethylammonium bromide (CTAB), negatively charged clusters self‐assemble into micelle‐templated mesoporous silica, [ 1 ] with sizes controllable down to single pore nanoparticles. [ 17 ] The addition of a pore expander increases micelle size, size dispersity, and deformability, [ 9,18 ] enabling cage‐like mesoporous structures. Numerous studies have identified bulk mesoporous materials formed from such cages as basic building blocks, [ 3,8,19 ] including 5 12 , 5 12 6 2 , or 5 12 6 3 cages, where 5 x 6 y refers to a cage made of x pentagonal and y hexagonal faces.…”

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Two‐Dimensional Superstructures of Silica Cages

Aubert

Tan

et al. 2020

Advanced Materials

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observed structure formation, we assembled mesoporous silica at an interface between two immiscible liquids. Careful variation of synthesis conditions allowed the formation of a number of different 2D cage-like silica superstructures with controlled number of layers.Base-catalyzed hydrolysis of alkoxysilane precursors in water produces primary silica clusters of about 2 nm diameter [10,15] that can further condense to form ultrasmall (<10 nm) silica nanoparticles. [16] In the presence of cationic surfactants such as cetyltrimethylammonium bromide (CTAB), negatively charged clusters self-assemble into micelle-templated mesoporous silica, [1] with sizes controllable down to single pore nanoparticles. [17] The addition of a pore expander increases micelle size, size dispersity, and deformability, [9,18] enabling cage-like mesoporous structures. Numerous studies have identified bulk mesoporous materials formed from such cages as basic building blocks, [3,8,19] including 5 12 , 5 12 6 2 , or 5 12 6 3 cages, where 5 x 6 y refers to a cage made of x pentagonal and y hexagonal faces. In contrast, details of the self-assembly processes involved in their formation, in particular the transition from a single cage to a 3D superstructure, often remains obscure. In this work, the controlled growth of 2D cage-based mesoporous silica enabled the direct real-space observation of structure evolution and the emergence of 3D order in those superstructures, one layer at a time. To the best of our knowledge, no such singlelayer mesoporous silica films have ever been reported. These superstructures constitute a hitherto unknown type of material bridging the field of mesoporous materials with that of 2D materials. For example, borrowing ideas from the field of 2D electronic materials, [20] results open scalable synthetic approaches to mesoporous silica heterostacks with property profiles inaccessible to date.In order to create large liquid−liquid interfacial area for the confined growth of 2D mesoporous superstructures, a relatively large amount of an oil phase, namely cyclohexane, was dispersed in an equivalent volume of water under vigorous stirring, forming large droplets stabilized by CTAB. Tetramethyl orthosilicate (TMOS) was combined with (3-aminopropyl) trimethoxy silane (APTMS) as silica sources. Under basic conditions, neutral aminopropyl groups of APTMS intercalate the surfactant layer due to their hydrophobicity, [21] serving as anchor points for primary silica clusters at the oil−surfactant−water interface. [15] This nucleates silica layer growth at the surface of the oil droplets as verified by Despite extensive studies on mesoporous silica since the early 1990s, the synthesis of two-dimensional (2D) silica nanostructures remains challenging. Here, mesoporous silica is synthesized at an interface between two immiscible solvents under conditions leading to the formation of 2D superstructures of silica cages, the thinnest mesoporous silica films synthesized to date. Orientational correlations between cage units increase with...

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Two‐Dimensional Superstructures of Silica Cages

Aubert

Tan

et al. 2020

Advanced Materials

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“…(vi)Other authors speak of spatially localized grains. For example, in [56] such grains are fabricated by manipulating nanoparticles, e.g. by stirring.…”

Section: Appendix Terminologymentioning

confidence: 99%

Spatially localized quasicrystalline structures

et al. 2018

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Soft matter systems have been observed to self-assemble, over a range of system parameters, into quasicrystalline structures. The resulting quasicrystals (QCs) may minimize the free energy, and be in thermodynamic coexistence with the liquid state. At such state points, the likelihood of finding the presence of spatially localized states with quasicrystalline structure within the liquid is increased. Here we report the first examples of metastable spatially localized QCs of varying sizes in both two and three dimensions. Implications of these results for the nucleation of quasicrystalline structures are discussed. Our conclusions apply to a broad class of soft matter systems and more generally to continuum systems exhibiting quasipatterns.

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“…By taking advantage of accessible quasicrystalline phases in somatter systems (surfactant micelles in particular), it is possible to template the formation of mesoporous silica with similar order. [44][45][46] These methods offer an accessible approach to porous quasicrystals, on the one hand enabling studies of the interactions of guest molecules with porous quasicrystalline hosts, on the other hand providing, perhaps, an alternative pathway towards quasicrystalline MOFs.…”

Section: Examples Of Aperiodic Structures In Mofs and Cpsmentioning

confidence: 99%