高等学校化学学报 ›› 2021, Vol. 42 ›› Issue (6): 1694.doi: 10.7503/cjcu20200869
收稿日期:
2020-12-16
出版日期:
2021-06-10
发布日期:
2021-06-08
通讯作者:
张春玲
E-mail:clzhang@jlu.edu.cn
基金资助:
LI Peihong, ZHANG Chunling(), DAI Xueyan, SUI Yanlong
Received:
2020-12-16
Online:
2021-06-10
Published:
2021-06-08
Contact:
ZHANG Chunling
E-mail:clzhang@jlu.edu.cn
Supported by:
摘要:
氧化石墨烯是一种具有单原子厚度的二维材料, 具有优异的力学性能和良好的水分散性, 其表面有大量的含氧官能团. 将氧化石墨烯引入水凝胶体系中可以提高水凝胶的机械性能, 丰富其刺激响应的类型. 目前, 氧化石墨烯水凝胶在高强度、 吸附、 自愈合及智能材料等很多领域均有出色的表现. 氧化石墨烯水凝胶的研究已有10年的历史. 本文总结了氧化石墨烯水凝胶的制备方法, 归纳了智能氧化石墨烯水凝胶在光热响应、 pH响应和自愈合3个方面的响应机理和研究进展, 并综合评述了其在高强度水凝胶、 生物医学、 智能材料和污水处理等方面的应用前景.
中图分类号:
TrendMD:
李佩鸿, 张春玲, 戴雪岩, 隋颜隆. 氧化石墨烯/聚合物复合水凝胶的研究进展. 高等学校化学学报, 2021, 42(6): 1694.
LI Peihong, ZHANG Chunling, DAI Xueyan, SUI Yanlong. Progress of Graphene Oxide/Polymer Composite Hydrogel. Chem. J. Chinese Universities, 2021, 42(6): 1694.
GO hydrogel | Gelation method | Gelation driving force | Performance and use | Ref. |
---|---|---|---|---|
GO/PVA | Mixing, sonication | H?bond | pH response | [ |
GO/PVA | Mixing, freeze?thaw | H?bond | pH response, self?healing, thermal stability | [ |
GO?RCE/PVA | Mixing, freeze?thaw | H?bond | pH response | [ |
GO/B?PVA/KCl | Mixing | Covalent bond, H?bond | Conductivity, self?healing | [ |
GO/SA/PVA | Mixing, freeze?thaw | H?bond | High strength, high swelling rate | [ |
GO/SA/NFA | Mixing | H?bond, ionic bond | Adsorption | [ |
GO/CS | Mixing | H?bond, electrostatic interaction | High strength, pH response | [ |
GO/CS | Mixing | Electrostatic interaction | Photo?thermal response | [ |
GO/QCEG/GM | Polymerization | Covalent bond | Photo?thermal response, conductivity, wound dressing | [ |
GO?Ag/CH | Mixing | H?bond | pH response, drug delivery | [ |
GO/CMC | Mixing | H?bond | pH response, drug delivery | [ |
GO/DNA | Mixing, heating | H?bond, electrostatic interaction, π?π stacking, hydrophobic interaction | Adsorption, self?healing | [ |
GO/PEI | Mixing, sonication | H?bond, electrostatic interaction | Adsorption | [ |
GO/F127 | Mixing | H?bond | pH response, drug delivery | [ |
GO/PyGAGAGY | Mixing | π?π stacking | Photo?thermal response, drug delivery | [ |
GO/Hb | Mixing | Electrostatic interaction | Enzyme catalysis | [ |
GO hydrogel | Gelation method | Gelation driving force | Performance and use | Ref. |
GO/KGM | Mixing | H?bond | Drug delivery | [ |
GO/PNIPAM | Polymerization | Covalent bond | Photo?thermal response | [ |
GO/PNIPAM/CS | Polymerization | Covalent bond | Stretchability, conductivity, self?healing | [ |
GO/P(NIPAM?MAA) | PEI crosslinking | Covalent bond, H?bond | Thermal and pH responsive membrane | [ |
GO/PNIPAM GO/PDMAA | Polymerization | Covalent bond | Self?healing, photo?thermal response, NIR drive valve | [ |
GO/Laponite/P(AMPS?co?DMAAm) | Polymerization | Covalent bond, H?bond | Thermal response, injectable | [ |
GO/gelation | NTP crosslinking | Covalent bond | Cartilage reconstructive | [ |
GO/cellulose | ECH crosslinking | Covalent bond | Adsorption, compression resistance | [ |
GO/PAA/cellulose | Electro beam radiation | Covalent bond | Wound dressing | [ |
PDA/pGO/PAM | Mixing, polymerization | Covalent bond, H?bond, electrostatic interaction, π?π stacking | High strength, conductivity, adhesion, self?healing | [ |
GO/PAM | Polymerization | Covalent bond, ionic bond | Stretchability | [ |
GO/P(AM?co?DAC) | Polymerization | Covalent bond, ionic bond, H?bond | High strength, compression resistance, self?healing | [ |
GO/PAA?g?AM | Mixing | H?bond, electrostatic interaction | Thermal stability, high strength | [ |
GO/PAA | Polymerization | Covalent bond, ionic bond | High strength, self?healing | [ |
GO/PAACA | Polymerization | Covalent bond, ionic bond | Stretchability | [ |
GO/PSBMA | Polymerization | Covalent bond | High strength, lubricity, artificial cartilage | [ |
GO/PPy | Polymerization | Covalent bond, H?bond, electrostatic interaction, π?π stacking | Gas sensor | [ |
Table 1 A series of GO/polymer composite hydrogels
GO hydrogel | Gelation method | Gelation driving force | Performance and use | Ref. |
---|---|---|---|---|
GO/PVA | Mixing, sonication | H?bond | pH response | [ |
GO/PVA | Mixing, freeze?thaw | H?bond | pH response, self?healing, thermal stability | [ |
GO?RCE/PVA | Mixing, freeze?thaw | H?bond | pH response | [ |
GO/B?PVA/KCl | Mixing | Covalent bond, H?bond | Conductivity, self?healing | [ |
GO/SA/PVA | Mixing, freeze?thaw | H?bond | High strength, high swelling rate | [ |
GO/SA/NFA | Mixing | H?bond, ionic bond | Adsorption | [ |
GO/CS | Mixing | H?bond, electrostatic interaction | High strength, pH response | [ |
GO/CS | Mixing | Electrostatic interaction | Photo?thermal response | [ |
GO/QCEG/GM | Polymerization | Covalent bond | Photo?thermal response, conductivity, wound dressing | [ |
GO?Ag/CH | Mixing | H?bond | pH response, drug delivery | [ |
GO/CMC | Mixing | H?bond | pH response, drug delivery | [ |
GO/DNA | Mixing, heating | H?bond, electrostatic interaction, π?π stacking, hydrophobic interaction | Adsorption, self?healing | [ |
GO/PEI | Mixing, sonication | H?bond, electrostatic interaction | Adsorption | [ |
GO/F127 | Mixing | H?bond | pH response, drug delivery | [ |
GO/PyGAGAGY | Mixing | π?π stacking | Photo?thermal response, drug delivery | [ |
GO/Hb | Mixing | Electrostatic interaction | Enzyme catalysis | [ |
GO hydrogel | Gelation method | Gelation driving force | Performance and use | Ref. |
GO/KGM | Mixing | H?bond | Drug delivery | [ |
GO/PNIPAM | Polymerization | Covalent bond | Photo?thermal response | [ |
GO/PNIPAM/CS | Polymerization | Covalent bond | Stretchability, conductivity, self?healing | [ |
GO/P(NIPAM?MAA) | PEI crosslinking | Covalent bond, H?bond | Thermal and pH responsive membrane | [ |
GO/PNIPAM GO/PDMAA | Polymerization | Covalent bond | Self?healing, photo?thermal response, NIR drive valve | [ |
GO/Laponite/P(AMPS?co?DMAAm) | Polymerization | Covalent bond, H?bond | Thermal response, injectable | [ |
GO/gelation | NTP crosslinking | Covalent bond | Cartilage reconstructive | [ |
GO/cellulose | ECH crosslinking | Covalent bond | Adsorption, compression resistance | [ |
GO/PAA/cellulose | Electro beam radiation | Covalent bond | Wound dressing | [ |
PDA/pGO/PAM | Mixing, polymerization | Covalent bond, H?bond, electrostatic interaction, π?π stacking | High strength, conductivity, adhesion, self?healing | [ |
GO/PAM | Polymerization | Covalent bond, ionic bond | Stretchability | [ |
GO/P(AM?co?DAC) | Polymerization | Covalent bond, ionic bond, H?bond | High strength, compression resistance, self?healing | [ |
GO/PAA?g?AM | Mixing | H?bond, electrostatic interaction | Thermal stability, high strength | [ |
GO/PAA | Polymerization | Covalent bond, ionic bond | High strength, self?healing | [ |
GO/PAACA | Polymerization | Covalent bond, ionic bond | Stretchability | [ |
GO/PSBMA | Polymerization | Covalent bond | High strength, lubricity, artificial cartilage | [ |
GO/PPy | Polymerization | Covalent bond, H?bond, electrostatic interaction, π?π stacking | Gas sensor | [ |
Fig.3 Temperature response and curvature change of the bilayer hydrogel in water with different temperatures(A), bilayer hydrogel in the air under NIR irradiation(B) and bilayer hydrogel folding and recovery with and without NIR irradiation in water(C)[49]The scale bars are 1?cm. Copyright 2019, Elsevier B. V.
Fig.5 Self?healing process of GO/DNA hydrogel[62]The hydrogel was cut into three small blocks and the blocks could adhere to each other by pushing the freshly formed surfaces to contact together followed by heating at 90 ℃ in air for 3 min. Copyright 2010, American Chemical Society.
Fig.6 Self?healing process of P(AM?co?DAC)/GO hydrogel[64]A sample was cut in half, then the two-halves were simply made to contact and a drop of water was dropped on the cut surface. After standing for hours, the sample can be stretched to a large strain. Copyright 2017, American Chemical Society.
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