Preparation and Research Progress of Polymer-based Flexible Conductive Composites
Vol 1, Issue 1, 2018
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Abstract
The development of flexible, wearable electronic devices is one of the future directions of technology development. Flexible conductive materials are important supporting materials for wearable electronic devices. Polymer has excellent flexibility; it is an important way to prepare flexible conductors from polymer-based conductive composites. In this paper, the research progress of polymer-based flexible conductive composites is summarized in terms of preparation and characterization methods. The key factors to realize flexible conductors are put forward, namely, the maintenance of excellent polymer elasticity and the realization of stability. The design and preparation of the extensible conductor with high-elasticity matrix and nanofiller are introduced in detail, and the problems in the current research are summarized.
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1. Sekitani T, Yokota T, Zschieschang U, et al. Organic nonvolatile memory transistors for flexible sensor arrays. Science 2009; 326: 1516-1519.
2. Benight SJ, Wang C, Tok JBH, et al. Stretchable and selfhealing polymers and devices for electronic skin. Progress in Polymer Science 2013; 38(12): 1961-1977.
3. Rogers J A, Someya T, Huang Y. Materials and mechanics for Stretchable electronics. Science 2010; 327: 1603-1607.
4. Sekitani T, Noguchi Y, Hata K, et al. A rubberlike stretchable Active matrix using popularity around. Science 2008; 321: 1468-1472.
5. Li Y, Shimizu H. Toward a stretchable, elastic, and electrically Conductive nanocomposite: morphology and properties of poly[Styrene-b- (ethylene-co-butylene) - B-styrene / multiwalled carbon Nanotube composites fabricated by high-shear processing. Macromolecules 2009; 42: 2587-2593.
6. Li Y, Zhao L, Shimizu H. Electrically conductive Materials with high stretchability and excellent elasticity by a surface coating method. Macromolecular Rapid Communications 2011; 32: 289-294.
7. Song L, Myers AC, Adams JJ, et al. Stretchable and reversibly deformable radio frequency eth based on silver nanowires. ACS Applied Materials & Interfaces 2014; 6: 4248-4253.
8. Fan JA, Yeo WH, Su Y, et al. Fractal design concepts for stretchable electronics. Nature Communications 2014; 5: 163-180.
9. Shin MK, Oh J, Lima M, et al. Elastomeric conductive composites Based on carbon nanotube forests. Advanced Materials 2010; 22: 2663-2667.
10. Wang X, Hu H, Shen Y, et al. Stretchable ultrahigh tensile strain and stable metallic conductance enabled by prestrained polyelectrolyte nanoplatforms. Advanced Materials 2011; 23: 3090-3094.
11. Xu F, Zhu Y. Highly conductive and stretchable silver nanowire. Advanced Materials 2012; 24: 5117-5122.
12. Zhang Y, Sheehan CJ, Zhai J, et al. Polymer-embedded carbon Nanotube ribbons for stretchable donor. Advanced Materials 2010; 22: 3027-3031.
13. Zhu Y, Xu F. Buckling of aligned carbon nanotubes as stretchable A new manufacturing strategy. Advanced Materials 2012; 24: 1073-1077.
14. Lin L, Liu S, Fu S, et al. Fabrication of highly stretchable advertising via morphological control of carbon nanotube network. Small 2013; 9: 3620-3629.
15. Kim KH, Vural M, Islam MF. Single-walled carbon nanotube Aerogel-based public around. Advanced Materials 2011; 23: 2865-2869.
16. Hu H, Zhao Z, Wan W, et al. Ultralight and highly compressible Graphene aerogels. Advanced Materials 2013; 25: 2219-2223.
17. Hu H, Zhao Z, Wan W, et al. Polymer / graphene hybrid aerogel With high compressibility, conductivity, and 'sticky' superhydrophobicity. ACS Applied Materials & Interfaces 2014; 6: 3242-3249.
18. Zhao L, Li Y, Qiu J, et al. Reactive bonding mediated high Mass loading of individualized single-walled carbon nanotubes in an elastomeric polymer. Nanoscale 2012; 4: 6613-6621.
19. Kim TA, Kim HS, Lee SS, et al. Single-walled carbon Nanotube / silicone rubber composites for compliant electrodes. Carbon 2012; 50: 444-449.
20. Shang S, Gan L, Yuen MCW, et al. Carbon nanotubes based high temperature vulcanized silicone rubber nanocomposite with excellent elasticity and electrical properties. Composites Part A 2014; 66: 135-141.
21. Shang S, Zeng W, Tao XM. High stretchable MWNTs / urethane guided nanocomposites. Journal of Materials Chemistry 2011; 21: 7274-7280.
22. Liu ZF, Fang S, Moura FA, et al. Hierarchically buckled sheath-core fibers for superelastic electronics, sensors, and muscle. Science 2015; 349: 400-404.
23. Jiang S, Zhang H, Song S, et al. Highly stretchable fiber from few-walled carbon nanotubes coated on poly (m-phenylene isophthalamide) polymer core / shell structures. ACS Nano 2015; 9: 10252-10257.
24. Ma R, Kang B, Cho S, et al. Extraordinarily high conductivity of stretchable fibers of polyurethane and silver nanoflowers. ACS Nano 2015; 9: 10876-10886.
25. Persano L, Dagdeviren C, Su Y, et al. High performance piezoelectric devices based on aligned arrays of nanofibers of poly (vinylidenefluoride-co-trifluoroethylene). Nature Communications 2013; 4: 67-88.
26. Sun B, Long YZ, Liu S L, et al. Fabrication of curled conduc-ting polymer microfibrous arrays via a novel electrospinning Method for stretchable strain sensors. Nanoscale 2013; 5: 7041-7045.
27. Boland CS, Khan U, Backes C, et al. Sensitive, high-strain, high-rate bodily motion sensors based on graphene- rubber composites. ACS Nano 2014; 8: 8819-8830.
28. Ding H, Zhong M, Kim YJ, et al. Biologically derived soft conducting hydrogels using heparin-doped polymer networks. ACS Nano 2014; 8: 4348-4357.
29. Kujawski M, Pearse JD, Smela E. Elastomers filled with exfoliated graphite as compliant electrodes. Carbon 2010; 48: 2409-2417.
DOI: https://doi.org/10.24294/jpse.v1i1.243
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