Crystal networks in supramolecular gels: formation kinetics and mesoscopic engineering principles

Yu, Rui; Lin, Naibo; Yu, Weidong; Liu, Xiang Yang

doi:10.1039/c5ce00854a

Cited by 43 publications

(50 citation statements)

References 113 publications

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“…Crucially, the ability to model heterogeneous nanocomposites has significance well beyond the example of ferrihydrite, as important as this system may be. For example, there are closelyrelated geologically-and biologically-relevant materials for which the approach we develop here is likely to offer significant insight: the structure and transformations of amorphous calcium phosphate, a key precursor in bone formation [57][58][59][60] ; crystallite nucleation in supramolecular gels 61 ; nanodomain evolution in aqueous aerosols 62 ; and the stabilising effects of porous functionalised silica on surrounding media 63 . Likewise, key components used in functional devices, such as battery cathodes, routinely contain mixtures of amorphous and nanostructured components and are not well described in terms of single-phase approximants 64 .…”

Section: Discussionmentioning

confidence: 99%

Nanocomposite structure of two-line ferrihydrite powder from total scattering

et al. 2020

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Ferrihydrite is one of the most important iron-containing minerals on Earth. Yet determination of its atomic-scale structure has been frustrated by its intrinsically poor crystallinity. The key difficulty is that physically-different models can appear consistent with the same experimental data. Using X-ray total scattering and a nancomposite reverse Monte Carlo approach, we evaluate the two principal contending models-one a multi-phase system without tetrahedral iron(III), and the other a single phase with tetrahedral iron(III). Our methodology is unique in considering explicitly the complex nanocomposite structure the material adopts: namely, crystalline domains embedded in a poorly-ordered matrix. The multi-phase model requires unphysical structural rearrangements to fit the data, whereas the single-phase model accounts for the data straightforwardly. Hence the latter provides the more accurate description of the short-and intermediate-range order of ferrihydrite. We discuss how this approach might allow experiment-driven (in)validation of complex models for important nanostructured phases beyond ferrihydrite.

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Section: Discussionmentioning

confidence: 99%

Nanocomposite structure of two-line ferrihydrite powder from total scattering

et al. 2020

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“…In this sense, they are ideal materials to wrap fibrous sensors. Concerning flexible materials engineering, the latest studies reveal that the performance of soft materials is directly correlated with four structural factors: the topology of the structural networks, the correlation length, the orientation, and the interactions of structural units of the mesoscopic structure . Based on these principles, the functionality of soft materials can be modified to add certain functional components to their mesoscopic network structure to endow the materials with additional functions (cf.…”

Section: Introductionmentioning

confidence: 99%

Silk Composite Electronic Textile Sensor for High Space Precision 2D Combo Temperature–Pressure Sensing

Hou

et al. 2019

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Wearable electronic textiles based on natural biocompatible/biodegradable materials have attracted great attention due to applications in health care and smart clothes. Silkworm fibers are durable, good heat conductors, insulating, and biocompatible, and are therefore regarded as excellent mediating materials for flexible electronics. In this paper, a strategy on the design and fabrication of highly flexible multimode electronic textiles (E-textile) based on functionalized silkworm fiber coiled yarns and weaving technology is presented. To achieve enhanced temperature sensing performance, a mixture of carbon nanotubes and an ionic liquid ([EMIM] Tf 2 N) is embedded, which displays top sensitivity of 1.23% °C −1 and stability compared with others. Furthermore, fibrous pressure sensing based on the capacitance change of each cross-point of two yarns gives rise to highly position dependent and sensitivity sensing of 0.136 kPa −1 . Based on weaving technologies, a unique combo textile sensor, which can sense temperature and pressure independently with a position precision of 1 mm 2 , is obtained. The application to intelligent gloves endows the position dependent sensing of the weight, and temperature distribution sensing of the temperature.

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“…It follows that many mesoscopic structures of silk are connected into mesoscopic crystal networks (Figure ). [3b,8] Therefore, the manipulation and control of mesoscopic network structures are the key step to control the macroscopic performance of soft materials. According to the latest research, the silk fibroin regenerated materials are of hierarchical nanofibril network structures, which can be controlled by several methods, such as additional alcohols, shear force, ultrasound etc.…”

Section: Introductionmentioning

confidence: 99%

Functionalization of Silk Fibroin Materials at Mesoscale

Lin

Cao

Huang

et al. 2016

Adv Funct Materials

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Silk fibers spun by silkworms or spiders at ambient temperature display unique mechanical strength, excellent biocompatibility and optical transparency, which offer unconventional interfaces to soft and curved biological systems. In comparison with conventional materials, the performance of soft matter, i.e., animal silks, is mainly determined by the structure at the mesoscale. To further extend the applications, functionalization of silk materials becomes is required, and mesoscopic material assembly (MMA) was developed for this task. This feature article provides an overview on the principles and strategies concerning MMA, and some typical examples of functionalizing silk fibroin materials. The main strategies of MMA include in vivo and in vitro assemblies, and can be implemented by the three different paths: (1) molecular recognition, (2) surface functionalization of nanomaterials, or (3) foreign molecule mediation. The cases include the functionalization of silk fibroin materials by one/two-photon fluorescent molecules, quantum dots (QDs) and gold clusters, etc. The applications of these functionalized materials in bio waveguide, white-light-emitting devices, bioimaging, were also highlighted. MMA provides a practical tool for the production of the functionalized biocompatible materials, which can be further applied to fabricate high-performance bio integrated devices used in consumer electronics, and biomedical diagnosis, as well as human-machine interfaces.

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Crystal networks in supramolecular gels: formation kinetics and mesoscopic engineering principles

Cited by 43 publications

References 113 publications

Nanocomposite structure of two-line ferrihydrite powder from total scattering

Nanocomposite structure of two-line ferrihydrite powder from total scattering

Silk Composite Electronic Textile Sensor for High Space Precision 2D Combo Temperature–Pressure Sensing

Functionalization of Silk Fibroin Materials at Mesoscale

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