基于纳米几丁质的超轻强韧气凝胶，可用于制备防水隔热材料。

Ultralight and robust aerogels based on nanochitin towards water-resistant thermal insulators.

机构信息

College of Chemistry and Environmental Engineering, Shenzhen University, Shenzhen, Guangdong, 518060, China; Biomass Molecular Engineering Center, School of Forestry and Landscape Architecture, Anhui Agricultural University, Hefei, Anhui, 230036, China.

Biomass Molecular Engineering Center, School of Forestry and Landscape Architecture, Anhui Agricultural University, Hefei, Anhui, 230036, China.

出版信息

Carbohydr Polym. 2020 Nov 15;248:116755. doi: 10.1016/j.carbpol.2020.116755. Epub 2020 Jul 13.

DOI:10.1016/j.carbpol.2020.116755

PMID:32919557

Abstract

The development of lightweight, strong and high-performance thermal insulators from renewable biomass are highly desired for sustainable development. Here, ultralight aerogels based on renewable nanochitin with outstanding mechanical properties, excellent water-resistant, and promising thermal insulation properties are fabricated. The pristine nanochitin aerogels (PNCAs) assembled from mechanically strong carboxylated chitin nanorods are firstly prepared through acid-induced gelation and supercritical drying. The resultant PNCAs present tunable density (10-50 mg/cm) and strong mechanical stiffness (the specific compression modulus of 30.2 MPa cm/g) combining with low thermal conductivity (27.2 mW/m K). After a facile silylation modification, the silylated nanochitin aerogels (SNCAs) exhibit hydrophobic behavior (contact angle >130°), improved compression performance (the specific compression modulus of 65 MPa cm/g), and promising thermal insulation property (30.5-35.8 mW/m K). Moreover, the silylated aerogel shows a negligible loss of mechanical performance when exposed to water for 12 h at 35 °C.

摘要

从可再生生物质中开发出轻量、高强和高性能的热绝缘体，是可持续发展的迫切需求。在此，我们制备了基于可再生纳米几丁质的超轻气凝胶，其具有出色的机械性能、优异的耐水性和有前景的隔热性能。通过机械强度高的羧基化甲壳素纳米棒的酸诱导凝胶化和超临界干燥，首先制备了由机械强度高的羧基化甲壳素纳米棒组装而成的原始纳米几丁质气凝胶（PNCAs）。所得的 PNCAs 具有可调的密度（10-50 mg/cm）和强机械刚度（比压缩模量为 30.2 MPa cm/g），同时具有低热导率（27.2 mW/m K）。经过简单的硅烷化修饰，硅烷化纳米几丁质气凝胶（SNCAs）表现出疏水性（接触角>130°）、改善的压缩性能（比压缩模量为 65 MPa cm/g）和有前景的隔热性能（30.5-35.8 mW/m K）。此外，在 35°C 下用水浸泡 12 小时后，硅烷化气凝胶的机械性能几乎没有损失。

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基于纳米几丁质的超轻强韧气凝胶，可用于制备防水隔热材料。

Ultralight and robust aerogels based on nanochitin towards water-resistant thermal insulators.

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