|本期目录/Table of Contents|

[1]匡中文,苑苗发,刘爱萍.纳米海绵诱导的各向异性水凝胶的驱动行为研究[J].浙江理工大学学报,2022,47-48(自科六):821-828.
 KUANG Zhongwen,YUAN Miaofa,LIU Aiping.Study on driving behavior of the anisotropic hydrogel induced by nano sponge[J].Journal of Zhejiang Sci-Tech University,2022,47-48(自科六):821-828.
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纳米海绵诱导的各向异性水凝胶的驱动行为研究()
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浙江理工大学学报[ISSN:1673-3851/CN:33-1338/TS]

卷:
第47-48卷
期数:
2022年自科第六期
页码:
821-828
栏目:
出版日期:
2022-11-10

文章信息/Info

Title:
Study on driving behavior of the anisotropic hydrogel induced by nano sponge
文章编号:
1673-3851 (2022) 11-0821-08
作者:
匡中文苑苗发刘爱萍
浙江理工大学,a.材料科学与工程学院;b.理学院,杭州 310018
Author(s):
KUANG ZhongwenYUAN MiaofaLIU Aiping
a.School of Materials Science & Engineering; b.School of Science, Zhejiang Sci-Tech University, Hangzhou 310018, China
关键词:
明胶纳米海绵各向异性结构机械性能智能驱动器
分类号:
TB322
文献标志码:
A
摘要:
高含水量的水凝胶通常机械性能差、响应单一,严重限制了其作为软体驱动器的发展。为了制备出具有多响应和优异力学性能的智能水凝胶,以纳米海绵作为骨架,将明胶水凝胶加入其中并溢出一定厚度,从而获得具有双层各向异性结构的纳米海绵/明胶复合水凝胶。结果表明:纳米海绵/明胶复合水凝胶同时具备多种溶剂响应和优异的力学性能,与纯明胶水凝胶相比,复合水凝胶的拉伸应力和压缩应力从kPa级上升到MPa级;复合水凝胶改变了原始水凝胶的各向同性结构使其具备驱动能力,可以在多种离子溶液中弯曲变形,在3 mol/L的(NH 4) 2SO 4溶液中弯曲角度可达247°;复合水凝胶用作微流控阀门,能识别特定溶液并调控其通过阀门的速度。通过引入纳米海绵骨架有效地构造智能水凝胶的各向异性结构,并明显增强了水凝胶的力学性能和驱动能力,为智能水凝胶在微流控系统、智能驱动器和人工肌肉等领域的应用提供了新的思路。

参考文献/References:

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2Liu X Y, Liu J, Lin S T, et al. Hydrogel machinesJ. Materials Today, 2020, 36: 102-124.3Wehner M, Truby R L, Fitzgerald D J, et al. An integrated design and fabrication strategy for entirely soft, autonomous robotsJ. Nature, 2016, 536(7617): 451-455.

4Liu K K, Zhang Y, Cao H Q, et al. Programmable reversible shape transformation of hydrogels based on transient structural anisotropyJ. Advanced Materials, 2020, 32(28): 2001693.

5Luo R C, Wu J, Dinh N D, et al. Gradient porous elastic hydrogels with shape-memory property and anisotropic responses for programmable locomotionJ. Advanced Functional Materials, 2015, 25(47): 7272-7279.

6Jian Y K, Wu B Y, Le X X, et al. Antifreezing and stretchable organohydrogels as soft actuatorsJ. Research, 2019, 2019(6): 2384347.

7Zheng S Y, Shen Y Y, Zhu F B, et al. Programmed deformations of 3D-printed tough physical hydrogels with high response speed and large output forceJ. Advanced Functional Materials, 2018, 28(37): 1803366.

8Peng X, Liu T Q, Zhang Q, et al. Surface patterning of hydrogels for programmable and complex shape deformations by ion inkjet printingJ. Advanced Functional Materials, 2017, 27(33): 1701962.

9Jiang H Y, Fan L X, Yan S, et al. Tough and electro-responsive hydrogel actuators with bidirectional bending behaviorJ. Nanoscale, 2019, 11(5): 2231-2237.

10Tognato R, Armiento A R, Bonfrate V, et al. A stimuli-responsive nanocomposite for 3D anisotropic cell-guidance and magnetic soft roboticsJ. Advanced Functional Materials, 2019, 29(9): 1804647.

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备注/Memo

备注/Memo:
收稿日期: 2022-03-16
网络出版日期:2022-05-09
基金项目: 国家自然科学基金项目(51572242)
作者简介: 匡中文(1995-),男,江西九江人,硕士研究生,主要从事智能水凝胶材料方面的研究。
通信作者: 刘爱萍,E-mail:aipingwz@163.com
更新日期/Last Update: 2022-11-07