Research progress in preparation and application of conductive hydrogels

doi:10.16085/j.issn.1000-6613.2020-1196

Abstract

Abstract:

Conductive hydrogels, a type of novel hydrogels which organically combine hydrophilic matrix and conductive medium, have plentiful insights and opportunities in flexible electronic devices and other fields because of their excellent flexibility, adjustable mechanical properties and outstanding electrochemical performances. In this review, the research frontiers and trends of conductive hydrogel materials were provided. The methods of classification and preparation of conductive hydrogels were introduced, and their design and performance of conductive hydrogels were discussed. Furthermore, the application research progress of conductive hydrogel materials was expounded thoroughly, and their problems and challenges were concluded. Finally, the development trend of conductive hydrogel materials was prospected, and it was pointed out that the use of natural raw materials in the exploration of conductive hydrogels with high conductivity, stable mechanical properties, extreme temperature tolerance, biocompatibility and biodegradability would be the focus of further research, while optimizing flexible electronic devices and improving the output stability of devices would also become an important research direction. The research on the fabrications and applications of conductive hydrogels can promote the rapid development of flexible electronic functional materials.

Key words: hydrogels, conductive media, conductive hydrogels, hydrogel materials, flexible electronic devices

摘要：

导电水凝胶是一类将亲水性基质和导电介质有机结合的新型水凝胶，具有较高的柔韧性、可调的力学性能和优异的电化学性能，在柔性电子设备等领域具有广阔的应用前景。本文综述了导电水凝胶材料的研究前沿和动态，介绍了导电水凝胶的分类及制备方法，讨论了导电水凝胶的结构设计与性能，重点阐述了导电水凝胶材料的应用研究进展，归纳了导电水凝胶材料面临的问题与挑战，并展望了导电水凝胶材料的发展趋势，指出采用天然可再生资源为原料开发具有高导电性、力学性能稳定、耐极端温度、生物相容性和生物可降解的导电水凝胶将成为下一步研究重点，同时优化柔性电子装置、提高器件输出稳定性也将成为重要的研究方向之一。导电水凝胶的制备及应用研究将促进柔性电子功能材料领域的快速发展。

关键词: 水凝胶, 导电介质, 导电水凝胶, 水凝胶材料, 柔性电子设备

CLC Number:

TB34

WANG Siheng, YANG Xinxin, LIU He, SHANG Shibin, SONG Zhanqian. Research progress in preparation and application of conductive hydrogels[J]. Chemical Industry and Engineering Progress, 2021, 40(5): 2646-2664.

王思恒, 杨欣欣, 刘鹤, 商士斌, 宋湛谦. 导电水凝胶的制备及应用研究进展[J]. 化工进展, 2021, 40(5): 2646-2664.

Figures/Tables 9

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制备方法	导电介质	导电类型	阻抗/Ω	导电率/S·m^-1	参考文献
引入导电聚合物到水凝胶	PANI	电子	10²~10⁵	10^-3~10¹	[16,22,25]
	PPy		10²~10⁴	10^-2~10¹	[18,23]
	PEDOT∶PSS		10²~10³	10^-1~10¹	[17]
引入导电颗粒到水凝胶	金属	电子	10¹~10³	10^-2~10¹	[29-30,32]
	CNT		10³~10⁷	10^-3~10¹	[36-37]
	GO		10³~10⁵	10^-3~10⁰	[35,38]
引入导电离子到水凝胶	离子盐	离子	10²~10⁵	10^-2~10¹	[45,47]

制备方法	导电介质	导电类型	阻抗/Ω	导电率/S·m^-1	参考文献
引入导电聚合物到水凝胶	PANI	电子	10²~10⁵	10^-3~10¹	[16,22,25]
	PPy		10²~10⁴	10^-2~10¹	[18,23]
	PEDOT∶PSS		10²~10³	10^-1~10¹	[17]
引入导电颗粒到水凝胶	金属	电子	10¹~10³	10^-2~10¹	[29-30,32]
	CNT		10³~10⁷	10^-3~10¹	[36-37]
	GO		10³~10⁵	10^-3~10⁰	[35,38]
引入导电离子到水凝胶	离子盐	离子	10²~10⁵	10^-2~10¹	[45,47]

类别	水凝胶	导电介质	导电率 /S·m^-1	断裂伸长率/%	压缩模量 /MPa	应用	参考文献
PAA基导电水凝胶	PAA/PANI	PANI	5.12	1160	N/A	传感器	[16]
	PAA/BaFe₁₂O₁₉	BaFe₁₂O₁₉	1.22	N/A	0.0871	传感器	[53]
	PAA/PEO-b-PLAA/KCl	KCl	1	9800	N/A	N/A	[19]
	PAA/PDMAPS/IL	PDMAPS/IL	1.2	10000	2.2	传感器	[55]
PAAm基导电水凝胶	P(AGA-co-AAm)/Fe³⁺	Fe³⁺	2.4	707	36.1	N/A	[58]
	PAAm/GO	GO	8.865	N/A	N/A	电池	[59]
	PAAm/SiO₂/H₃PO₄	H₃PO₄	1.7	1500	N/A	超级电容器	[60]
	PAAm/LiCl	LiCl	1	1000	N/A	触摸屏	[61]
PVA基导电水凝胶	PVA/HPC/NaCl	NaCl	3.4	975	N/A	传感器	[63]
	PVA/PANI	PANI	19	416	2.68	超级电容器	[64]
	PVA/植酸	植酸	13.4	1100	N/A	传感器	[65]
	PVA/PDA/GO	GO	2.7	415	N/A	传感器	[66]
	PVA/丝素蛋白/硼砂	硼砂	63	5000	N/A	传感器	[67]
PEG基导电水凝胶	（PEG/PEDOT）∶（PSS/H₂SO₄）	PEDOT∶（PSS/H₂SO₄）	1.69	N/A	0.021	组织工程支架	[69]
	PEG/PEDOT	PEDOT	N/A	N/A	1.28	传感器	[70]
	PEG/AgNWs	AgNWs	N/A	100	0.016	传感器	[71]
	PEG/Na₂SO₄	Na₂SO₄	N/A	N/A	N/A	离子电路	[44]

类别	水凝胶	导电介质	导电率 /S·m^-1	断裂伸长率/%	压缩模量 /MPa	应用	参考文献
PAA基导电水凝胶	PAA/PANI	PANI	5.12	1160	N/A	传感器	[16]
	PAA/BaFe₁₂O₁₉	BaFe₁₂O₁₉	1.22	N/A	0.0871	传感器	[53]
	PAA/PEO-b-PLAA/KCl	KCl	1	9800	N/A	N/A	[19]
	PAA/PDMAPS/IL	PDMAPS/IL	1.2	10000	2.2	传感器	[55]
PAAm基导电水凝胶	P(AGA-co-AAm)/Fe³⁺	Fe³⁺	2.4	707	36.1	N/A	[58]
	PAAm/GO	GO	8.865	N/A	N/A	电池	[59]
	PAAm/SiO₂/H₃PO₄	H₃PO₄	1.7	1500	N/A	超级电容器	[60]
	PAAm/LiCl	LiCl	1	1000	N/A	触摸屏	[61]
PVA基导电水凝胶	PVA/HPC/NaCl	NaCl	3.4	975	N/A	传感器	[63]
	PVA/PANI	PANI	19	416	2.68	超级电容器	[64]
	PVA/植酸	植酸	13.4	1100	N/A	传感器	[65]
	PVA/PDA/GO	GO	2.7	415	N/A	传感器	[66]
	PVA/丝素蛋白/硼砂	硼砂	63	5000	N/A	传感器	[67]
PEG基导电水凝胶	（PEG/PEDOT）∶（PSS/H₂SO₄）	PEDOT∶（PSS/H₂SO₄）	1.69	N/A	0.021	组织工程支架	[69]
	PEG/PEDOT	PEDOT	N/A	N/A	1.28	传感器	[70]
	PEG/AgNWs	AgNWs	N/A	100	0.016	传感器	[71]
	PEG/Na₂SO₄	Na₂SO₄	N/A	N/A	N/A	离子电路	[44]

类别	水凝胶	导电介质	导电率 /S·m^-1	断裂伸长率/%	压缩模量 /MPa	应用	参考文献
明胶基导电水凝胶	明胶/(NH₄)₂SO₄	（NH₄)₂SO₄	5	300	6.41	N/A	[73]
	明胶/PANI	PANI	4.54×10^-2	N/A	N/A	组织工程支架	[74]
	明胶/MWNT	MWNT	5×10^-2	160	N/A	传感器	[75]
	明胶/AgNWs/Na₂SO₄	AgNWs/Na₂SO₄	10	350	N/A	传感器	[76]
海藻酸盐基导电水凝胶	海藻酸钠/PAAm/CaCl₂	CaCl₂	N/A	2422	N/A	传感器	[79]
	海藻酸钠/PAAm/PAA/ZnSO₄	ZnSO₄	N/A	4200	N/A	传感器	[80]
	海藻酸钠/PAAm/CNT/(PEDOT∶PSS)	CNT/(PEDOT∶PSS)	0.048	1000	N/A	超级电容器	[81]
	海藻酸钠/PAAm/Na₂SO₄	Na₂SO₄	1.49	2400	N/A	超级电容器	[81]
壳聚糖基导电水凝胶	壳聚糖/PAAm/PPy	PPy	0.3	500	136.3	创面修复	[21]
	壳聚糖/AgNWs/AgNO₃	AgNWs/AgNO₃	0.48	N/A	N/A	传感器	[45]
	壳聚糖/AgNWs/CuSO₄	AgNWs/CuSO₄	0.25	N/A	N/A	传感器	[45]
	壳聚糖/PANI	PANI	743.7	N/A	N/A	N/A	[83]
纤维素基导电水凝胶	纤维素/PANI	PANI	3.47	N/A	4	超级电容器	[86]
	纤维素/[Bmim]Cl	[Bmim]Cl	4	100	N/A	传感器	[87]
	纤维素/(NH₄)₂S₂O₈	(NH₄)₂S₂O₈	0.016	126	0.036	传感器	[88]
	纤维素/PAAm/ZnSO₄/MnSO₄	ZnSO₄/MnSO₄	2.28	1400	N/A	电池	[89]