Phosphorus groups assisted growth of vertically oriented polyaniline nanothorns on N/P co-doped carbon nanofibers for high-performance supercapacitors

Electrochimica Acta

Volumn 216, Issue , 2016, Pages 355-363

  Fan, Xiaorong ^a   Yan, Xiaodong ^a,b   Yu, Yunhua ^a   Lan, Jinle ^a   Yang, Xiaoping ^a  

^a BEIJING UNIVERSITY OF CHEMICAL TECHNOLOGY   (China)

^b UNIVERSITY OF MISSOURI KANSAS CITY   (United States)

Author keywords

carbon nanofibers; composite; phosphorus; polyaniline; Supercapacitors

Indexed keywords

CAPACITANCE; CHARGE TRANSFER; COMPOSITE MATERIALS; NANOFIBERS; PHOSPHORUS; POLYANILINE;

CAPACITANCE RETENTION; CHARGE-TRANSFER DYNAMICS; ELECTROCHEMICAL PERFORMANCE; HIGH RATE CAPABILITY; HIGH SPECIFIC CAPACITANCES; IN-SITU POLYMERIZATION; ORIENTED POLYANILINES; SUPER CAPACITOR;

CARBON NANOFIBERS;

EID: 84987981925     PISSN: 00134686     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.electacta.2016.09.032     Document Type: Article

References (42)

1. [1] Simon, P., Gogotsi, Y., Materials for electrochemical capacitors. Nature Materials 7 (2008), 845–853.
2. [2] Li, X., Zhang, H., Wang, G., Jiang, G., A novel electrode material based on a highly homogeneous polyaniline/titanium oxide hybrid for high-rate electrochemical capacitors. Journal of Materials Chemistry 20 (2010), 10598–10601.
3. [3] Choi, N.-S., Chen, Z., Freunberger, S.-A., Ji, X., Sun, Y.-K., Khalil, A., Yushin, G., Nazar, L.-F., Cho, J., Bruce, P.-G., Challenges facing lithium batteries and electrical double-layer capacitors. Angewandte Chemie International Edition 51 (2012), 9994–10024.
4. [4] Yan, X., Yu, Y., Ryu, S., Lan, J., Jia, X., Yang, X., Simple and scalable synthesis of phosphorus and nitrogen enriched porous carbons with high volumetric capacitance. Electrochimica Acta 136 (2014), 466–472.
5. [5] Jin, Z., Yan, X., Yu, Y., Zhao, G., Sustainable activated carbonfibers from liquefied wood with controllable porosity for high performance supercapacitors. Journal of Materials Chemistry A 2 (2014), 11706–11715.
6. [6] Bose, S., Kuila, T., Mishra, A.K., Rajasekar, R., Kim, N.-H., Lee, J.-H., Carbon-based nanostructured materials and their composites as supercapacitor electrodes. Journal of Materials Chemistry 22 (2012), 767–784.
7. [7] Jang, Y., Jo, J., Choi, Y., Kim, I., Lee, S., Kim, D., Yoon, S.-M., Activated carbon nanocomposite electrodes for high performance supercapacitors. Electrochimica Acta 102 (2013), 240–245.
8. [8] Fan, L.-Z., Hu, Y.-S., Maier, J., Adelhelm, P., Smarsly, B., Antonietti, M., High electroactivity of polyaniline in supercapacitors by using a hierarchically porous carbon monolith as a support. Advanced Functional Materials 17 (2007), 3083–3087.
9. [9] Zhai, Y., Dou, Y., Zhao, D., Fulvio, P.-F., Mayes, R.-T., Dai, S., Carbon materials for chemical capacitive energy storage. Advanced Materials 23 (2011), 4828–4850.
10. [10] Wang, Q., Yan, J., Wei, T., Feng, J., Ren, Y., Fan, Z., Zhang, M., Jing, X., Two-dimensional mesoporous carbon sheet-like framework material for high-rate supercapacitors. Carbon 60 (2013), 481–487.
11. [11] Wang, Y., Shi, Z., Huang, Y., Ma, Y., Wang, C., Chen, M., Chen, Y., Supercapacitor devices based on graphene materials. The Journal of Physical Chemistry C 113 (2009), 13103–13107.
12. [12] Schultze, J.-W., Karabulut, H., Application potential of conducting polymers. Electrochimica Acta 50 (2005), 1739–1745.
13. [13] Li, C., Bai, H., Shi, G., Conducting polymer nanomaterials: electrosynthesis and applications. Chemical Society Reviews 38 (2009), 2397–2409.
14. 4 nanocrystals: Facile synthesis, controlled assembly, and application. Chemistry of Materials 22 (2010), 4232–4236.
15. [15] Zhi, M., Xiang, C., Li, J., Li, M., Wu, N., Nanostructured carbon–metal oxide composite electrodes for supercapacitors: a review. Nanoscale 5 (2013), 72–88.
16. [16] Yu, G., Xie, X., Pan, L., Bao, Z., Cui, Y., Hybrid nanostructured materials for high-performance electrochemical capacitors. Nano Energy 2 (2013), 213–234.
17. [17] Dai, W., Ma, L., Gan, M., Wang, S., Sun, X., Wang, H., Wang, H., Zhou, T., Fabrication of sandwich nanostructure graphene/polyaniline hollow spheres composite and its applications as electrode materials forsupercapacitor. Materials Research Bulletin 76 (2016), 344–352.
18. [18] Niu, Z., Luan, P., Shao, Q., Dong, H., Li, J., Chen, J., Zhao, D., Cai, L., Zhou, W., Chen, X., Xie, S., A “skeleton/skin” strategy for preparing ultrathin free-standing single-walled carbon nanotube/polyaniline films for high performance supercapacitor electrodes. Energy & Environmental Science 5 (2012), 8726–8733.
19. 5/MWCNT core/shell hybrid aerogels through a mixed growth and selfassembly methodology for supercapacitors with high capacitance and ultralong cycle life. Journal of Materials Chemistry 22 (2012), 767–784.
20. 2-carbon nanotube composite for high-areal-density supercapacitors with high rate performance. Journal of Power Sources 305 (2016), 30–36.
21. 2 coated on carbon spheres as excellent electrode materials for supercapacitors. RSC Advances 4 (2014), 6927–6932.
22. 2] loaded carbonfiber flexible electrode for high performance supercapacitor. RSC Advances 5 (2015), 56942–56948.
23. [23] Yu, S., Liu, D., Zhao, S., Bao, B., Jin, C., Huang, W., Chen, H., Shen, Z., Synthesis of wood derived nitrogen-doped porous carbon–polyaniline composites for supercapacitor electrode materials. RSC Advances 5 (2015), 30943–30949.
24. [24] Cheng, Q., Tang, J., Ma, J., Zhang, H., Shinya, N., Qin, L., Polyaniline-coated electro-etched carbon fiber cloth electrodes for supercapacitors. Journal of Materials Chemistry C 115 (2011), 23584–23590.
25. [25] Yang, J., Jang, I., Kim, M., Baeck, S.H., Hwang, S., Shim, S.E., Electrochemically polymerized vine-like nanostructured polyaniline on activated carbon nanofibers for supercapacitor. Electrochimica Acta 111 (2013), 136–143.
26. [26] Wang, Y., Tao, S., An, Y., Wu, S., Meng, C., Bio-inspired high performance electrochemical supercapacitors based on conducting polymer modified coral-like monolithic carbon. Journal of Materials Chemistry A, 1, 2013, 8876.
27. [27] Shi, K.Y., Zhitomirsky, I., Polypyrrole nanofiber–carbon nanotube electrodes for supercapacitors with high mass loading obtained using an organic dye as a co-dispersant. Journal of Materials Chemistry A 1 (2013), 11614–11622.
28. [28] Wang, Y.G., Li, H.Q., Xia, Y.Y., Ordered whiskerlike polyaniline grown on the surface of mesoporous carbon and its electrochemical capacitance performance. Advanced Materials 18 (2006), 2619–2623.
29. [29] Dirican, M., Yanilmaz, M., Zhang, X.W., Free-standing polyaniline–porous carbon nanofiber electrodes for symmetric and asymmetric supercapacitors. RSC Advances 4 (2014), 59427–59435.
30. [30] Lai, L., Yang, H., Wang, L., Teh, B.K., Zhong, J., Chou, H., Chen, L., Chen, W., Shen, Z., Ruoff, R.S., Lin, J., Preparation of supercapacitor electrodes through selection of graphene surface functionalities. ACS Nano 6 (2012), 5941–5951.
31. [31] Wang, Q., Yan, J., Fan, Z.J., Wei, T., Zhang, M.L., Jing, X.Y., Mesoporous polyaniline film on ultra-thin graphene sheets for high performance supercapacitors. Journal of Power Sources 247 (2014), 197–203.
32. [32] Zhao, Y., Zhang, Z., Ren, Y., Ran, W., Chen, X., Wu, J., Gao, F., Vapor deposition polymerization of aniline on 3D hierarchical porous carbon with enhanced cycling stability as supercapacitor electrode. Journal of Power Sources 286 (2015), 1–9.
33. [33] Wang, L., Ye, Y.J., Lu, X.P., Wen, Z.B., Li, Z., Hou, H.Q., Song, Y.H., Hierarchical nanocomposites of polyaniline nanowire arrays on reduced graphene oxide sheets for supercapacitors. Scientific reports, 3, 2013, 3568.
34. [34] Liu, Y., Deng, R.J., Wang, Z., Liu, H.T., Carboxyl-functionalized graphene oxide–polyaniline composite as a promising supercapacitor material. Journal of Materials Chemistry 22 (2012), 13619–13624.
35. [35] Yan, X., Liu, Y., Fan, X., Jia, X., Yu, Y., Yang, X., Nitrogen/phosphorus co-doped nonporous carbon nanofibers for high-performance supercapacitors. Journal of Power Sources 248 (2014), 745–751.
36. [36] Yan, X., Yu, Y., Yang, X., Effects of electrolytes on the capacitive behavior of nitrogen/phosphorus co-doped nonporous carbon nanofibers: an insight into the role of phosphorus groups. RSC Advances, 4, 2014, 24986.
37. [37] Li, Y.Z., Zhao, X., Xu, Q., Zhang, Q.H., Chen, D.J., Facile preparation and enhanced capacitance of the polyaniline/sodium alginate nanofiber network for supercapacitors. Langmuir 27 (2011), 6458–6463.
38. [38] Li, Z.-F., Zhang, H., Liu, Q., Sun, L., Stanciu, L., Xie, J., Fabrication of high-surface-area graphene/polyaniline nanocomposites and their application in supercapacitors. ACS Applied Materials & Interfaces 5 (2013), 2685–2691.
39. [39] Miao, F., Shao, C., Li, X., Wang, K., Lu, N., Liu, Y., Electrospun carbon nanofibers/carbon nanotubes/polyaniline ternary composites with enhanced electrochemical performance for flexible solid-state supercapacitors. ACS Sustainable Chemistry & Engineering 4 (2016), 1689–1696.
40. [40] Guo, F., Mi, H., Zhou, J., Zhao, Z., Qiu, J., Hybrid pseudocapacitor materials from polyaniline@multi-walled carbon nanotube with ultrafine nanofiber-assembled network shell. Carbon 95 (2015), 323–329.
41. [41] Lei, Z., Chen, Z., Zhao, X.S., Growth of polyaniline on hollow carbon spheres for enhancing electrocapacitance. Journal of Physical Chemistry C 114 (2010), 19867–19874.
42. [42] Zhang, L.L., Li, S., Zhang, J., Guo, P., Zheng, J., Zhao, X.S., Enhancement of electrochemical performance of macroporous carbon by surface coating of polyaniline. Chemistry of Materials 22 (2010), 1195–1202.