Anisotropic and hierarchical SiC@SiO
            <sub>2</sub>
            nanowire aerogel with exceptional stiffness and stability for thermal superinsulation

Su, Lei; Wang, Hongjie; Niu, Min; Dai, Sheng; Cai, Zhixin; Yang, Biguo; Huyan, Huaixun; Pan, Xiaoqing

doi:10.1126/sciadv.aay6689

Cited by 184 publications

(126 citation statements)

References 47 publications

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“…To solve this problem, researchers employed flexible fibers to construct aerogels to enhance the mechanical properties. [ 90–97 ]…”

Section: Processing Strategiesmentioning

confidence: 99%

“…This fusion and anisotropic microstructure of nanowires lead to high compression resilience. [ 96 ] Furthermore, the inorganic sol nanoparticles can also act as crosslinkers, forming a stable crosslinking structure between the nanofibers and nanoparticles. Dou et al.…”

Section: Processing Strategiesmentioning

confidence: 99%

“…Introducing fiber into inorganic aerogels: (A) inorganic nanofiber reinforce inorganic aerogel (reprinted with permission [ 96 ] ); (B) directional freeze drying method provide oriented structure (reprinted with permission [ 93 ] ); (C) organic nanofiber reinforce inorganic aerogel (reprinted with permission [ 94 ] )…”

Section: Processing Strategiesmentioning

confidence: 99%

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Recent advances in novel aerogels through the hybrid aggregation of inorganic nanomaterials and polymeric fibers for thermal insulation

et al. 2021

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Aerogel is a nanoporous solid material with ultrahigh porosity, ultralow density, and thermal conductivity, which is considered to be one of the most promising high‐performance insulation materials today. However, traditional pure inorganic aerogels (i.e., silica aerogel) exhibit inherent structural brittleness, making their processing and handling difficult, and their manufacturing costs are relatively high, which limits their large‐scale practical use. The recently developed aerogel based on polymer nanofibers has ultralow thermal conductivity and density, excellent elasticity, and designable multifunction. More importantly, one‐dimensional polymer nanofibers are directly used as building blocks to construct the network of aerogels via a gelation‐free process. This greatly simplifies the aerogel preparation process, thereby bringing opportunities for large‐scale aerogel applications. The aggregation of inorganic nanomaterials and polymer nanofibers is considered to be a very attractive strategy for obtaining highly flexible, easily available, and multifunctional composite aerogels. Therefore, this review summarizes the recent advances in novel aerogels through the hybrid aggregation of inorganic nanomaterials and polymeric fibers for thermal insulation. The main processing routes, porous microstructure, mechanical properties, and thermal properties and applications of these aerogels are highlighted. In addition, various future challenges faced by these aerogels in thermal insulation applications are discussed in this review.

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“…To solve this problem, researchers employed flexible fibers to construct aerogels to enhance the mechanical properties. [ 90–97 ]…”

Section: Processing Strategiesmentioning

confidence: 99%

Section: Processing Strategiesmentioning

confidence: 99%

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Recent advances in novel aerogels through the hybrid aggregation of inorganic nanomaterials and polymeric fibers for thermal insulation

et al. 2021

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“…Porous materials, such as wood and bones, widely exist in nature and have attracted great attention due to their low density, high specific strength, large specific surface area, and good mass permeability. [ 1 ] Hence, porous materials can be used for light‐weight materials, [ 2 ] energy, [ 3 ] material separation, [ 4 ] safety protection, [ 5 ] and tissue engineering. [ 6 ] To prepare porous materials, various methods have been developed, including direct synthesis, [ 7 ] phase separation, [ 8 ] templating, [ 9 ] foaming, [ 10 ] and 3D printing.…”

Section: Figurementioning

confidence: 99%

Programmable Local Orientation of Micropores by Mold‐Assisted Ice Templating

et al. 2020

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Pore geometry plays a crucial role in determining the properties and functions of porous materials. Various methods have been developed to prepare porous materials that have randomly distributed or well‐aligned pores. However, a technique capable of fine regulation of local pore orientation is still highly desired but difficult to attain. A technique, termed mold‐assisted ice templating (MIT), is reported to control and program the local orientation of micropores. MIT employs a copper mold of a particular shape (for instance a circle, square, hexagon, or star) and a cold finger to regulate the 3D orientation of a local temperature gradient, which directs the growth of ice crystals; this approach results in the formation of finely regulated patterns of lamellar pore structures. Moreover, the lamellar thickness and spacing can be tuned by controlling the solution concentration.

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“…24 This seminal work has inspired the development of a significant amount of nanowire aerogels including various ceramic, metal, metal oxide, metal phosphate nanowire aerogels. 26,38,40,41,[45][46][47][48][49] Different from the typical application of macroscopic-scale 2D assembled nanowires in thinfilm based electronic devices such as transistors, sensors and photodetectors, [50][51][52] the intrinsic properties of anisotropic nanowire building blocks combined with the structural characteristics of aerogels have promoted wide application of aerogels in many emerging fields including thermal insulator, 53 energy storage and conversion, 54 catalysis, 27 pollutants removal, 55 pressure sensor, 37 and solar steam generation. 56 As a matter of fact, the literature regarding nanowire aerogels is growing rapidly.…”

Section: Introductionmentioning

confidence: 99%

Fabrication and application of macroscopic nanowire aerogels

Niu

Zhao

et al. 2021

Nanoscale

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Anisotropic and hierarchical SiC@SiO ₂ nanowire aerogel with exceptional stiffness and stability for thermal superinsulation

Cited by 184 publications

References 47 publications

Recent advances in novel aerogels through the hybrid aggregation of inorganic nanomaterials and polymeric fibers for thermal insulation

Recent advances in novel aerogels through the hybrid aggregation of inorganic nanomaterials and polymeric fibers for thermal insulation

Programmable Local Orientation of Micropores by Mold‐Assisted Ice Templating

Fabrication and application of macroscopic nanowire aerogels

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Anisotropic and hierarchical SiC@SiO 2 nanowire aerogel with exceptional stiffness and stability for thermal superinsulation

Cited by 184 publications

References 47 publications

Recent advances in novel aerogels through the hybrid aggregation of inorganic nanomaterials and polymeric fibers for thermal insulation

Recent advances in novel aerogels through the hybrid aggregation of inorganic nanomaterials and polymeric fibers for thermal insulation

Programmable Local Orientation of Micropores by Mold‐Assisted Ice Templating

Fabrication and application of macroscopic nanowire aerogels

Contact Info

Product

Resources

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Anisotropic and hierarchical SiC@SiO ₂ nanowire aerogel with exceptional stiffness and stability for thermal superinsulation