Synthesis and electrochemical properties of nickel-manganese oxide on MWCNTs/CFP substrate as a supercapacitor electrode

Applied Energy

Volumn 153, Issue , 2015, Pages 78-86

  Li, Ya Hao ^a   Li, Qing Yu ^a   Wang, Hong Qiang ^a   Huang, You Guo ^a   Zhang, Xiao Hui ^a   Wu, Qiang ^a   Gao, Hong Quan ^b   Yang, Jian Hong ^b  

^a GUANGXI NORMAL UNIVERSITY   (China)

^b ALUMINUM CORPORATION OF CHINA LIMITED   (China)

Author keywords

3D carbon structure; Nickel manganese oxide; Nickel manganese oxide MWCNTs CFP composite; Supercapacitor

Indexed keywords

CAPACITORS; CARBON; CARBON FIBERS; CHEMICAL VAPOR DEPOSITION; DEPOSITION; ELECTROCHEMICAL ELECTRODES; ELECTROCHEMICAL PROPERTIES; ELECTRODES; ELECTROLYTIC CAPACITORS; ENERGY DISPERSIVE SPECTROSCOPY; MANGANESE; METALS; NICKEL; OXIDES; REDUCTION; SCANNING ELECTRON MICROSCOPY; TRANSMISSION ELECTRON MICROSCOPY; X RAY POWDER DIFFRACTION; X RAY SPECTROSCOPY; YARN;

CARBON STRUCTURES; CHEMICAL VAPOR DEPOSITIONS (CVD); ELECTRICAL CONDUCTIVITY; ELECTROCHEMICAL DEPOSITION PROCESS; ENERGY DISPERSIVE X RAY SPECTROSCOPY; NICKEL MANGANESE OXIDE; SUPER CAPACITOR; SUPERCAPACITOR ELECTRODES;

MANGANESE OXIDE;

ELECTRODE; ELECTROKINESIS; MANGANESE OXIDE; NICKEL; SUBSTRATE; THREE-DIMENSIONAL MODELING;

EID: 84930650646     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2014.09.055     Document Type: Article

References (68)

1. Tarascon J.-M., Armand M. Issues and challenges facing rechargeable lithium batteries. Nature 2001, 414:359-367.
2. Winter M., Brodd R.J. What are batteries, fuel cells, and supercapacitors?. Chem Rev 2005, 105:1021.
3. Simon P., Gogotsi Y. Materials for electrochemical capacitors. Nat Mater 2008, 7:845-854.
4. Pumera M. Graphene-based nanomaterials for energy storage. Energy Environ Sci 2011, 4:668-674.
5. Guo S., Dong S. Graphene nanosheet: synthesis, molecular engineering, thin film, hybrids, and energy and analytical applications. Chem Soc Rev 2011, 40:2644-2672.
6. Stoller M.D., Ruoff R.S. Best practice methods for determining an electrode material's performance for ultracapacitors. Energy Environ Sci 2010, 3:1294-1301.
7. Ghosh A., Lee Y.H. Carbon-based electrochemical capacitors. ChemSusChem 2012, 5:480-499.
8. Lokhande C.D., Dubal D.P., Joo O.-S. Metal oxide thin film based supercapacitors. Curr Appl Phys 2011, 11:255-270.
9. Di Noto V., Lavina S., Giffin G.A., Negro E., Scrosati B. Polymer electrolytes: present, past and future. Electrochim Acta 2011, 57:4-13.
10. Li S.-M., Wang Y.-S., Yang S.-Y., Liu C.-H., Chang K.-H., Tien H.-W., et al. Electrochemical deposition of nanostructured manganese oxide on hierarchically porous graphene-carbon nanotube structure for ultrahigh-performance electrochemical capacitors. J Power Sources 2013, 225:347-355.
11. Huang Y., Liang J., Chen Y. An overview of the applications of graphene-based materials in supercapacitors. Small 2012, 8:1805-1834.
12. Shukla A.K., Banerjee A., Ravikumar M.K., Jalajakshi A. Electrochemical capacitors: technical challenges and prognosis for future markets. Electrochim Acta 2012, 84:165-173.
13. Du C., Pan N. Carbon nanotube-based supercapacitors. Nanotech L Bus 2007, 4:3.
14. Jiang H., Lee P.S., Li C. 3D carbon based nanostructures for advanced supercapacitors. Energy Environ Sci 2013, 6:41.
15. Boyea J., Camacho R., Sturano S., Ready W. Carbon nanotube-based supercapacitors: technologies and markets. Nanotech L Bus 2007, 4:19.
16. Ma S.-B., Nam K.-W., Yoon W.-S., Yang X.-Q., Ahn K.-Y., Oh K.-H., et al. Electrochemical properties of manganese oxide coated onto carbon nanotubes for energy-storage applications. J Power Sources 2008, 178:483-489.
17. Song M.K., Cheng S., Chen H., Qin W., Nam K.W., Xu S., et al. Anomalous pseudocapacitive behavior of a nanostructured, mixed-valent manganese oxide film for electrical energy storage. Nano Lett 2012, 12:3483-3490.
18. 2 composites synthesized by microwave-assisted method for supercapacitors with high power and energy densities. J Power Sources 2009, 194:1202-1207.
19. 2 electrode used in aqueous electrochemical capacitor. Chem Mater 2004, 16:3184-3190.
20. 2 on well-aligned carbon nanotube arrays and its application in supercapacitors. Diam Relat Mater 2008, 17:1943-1948.
21. 2: large scale synthesis via a facile quick-redox procedure and application in a supercapacitor. New J Chem 2011, 35:469.
22. 2-built composite architecture and their enhanced electrochemical capacitance performance. J Mater Chem 2011, 21:17185.
23. 2 multilayer nanosheet clusters evolved from monolayer nanosheets and their predominant electrochemical properties. Electrochem Commun 2009, 11:706-710.
24. Li Q., Wang Z.L., Li G.R., Guo R., Ding L.X., Tong Y.X. Design and synthesis of MnO(2)/Mn/MnO(2) sandwich-structured nanotube arrays with high supercapacitive performance for electrochemical energy storage. Nano Lett 2012, 12:3803-3807.
25. Kosova N.V., Devyatkina E.T., Kaichev V.V. Mixed layered Ni-Mn-Co hydroxides: crystal structure, electronic state of ions, and thermal decomposition. J Power Sources 2007, 174:735-740.
26. 2O nanorods as a positive electrode material for supercapacitors. RSC Adv 2013, 3:6472.
27. 8 (M=Ni or Co) based nanostructures: a new family of high performance pseudocapacitive materials. J Mater Chem A 2014, 2:4919.
28. Luo J.-M., Gao B., Zhang X.-G. High capacitive performance of nanostructured Mn-Ni-Co oxide composites for supercapacitor. Mater Res Bull 2008, 43:1119-1125.
29. Huang Q., Zhang Z.-Y., Ma W.-J., Chen Y.-W., Zhu S.-M., Shen S.-B. A novel catalyst of Ni-Mn complex oxides supported on cordierite for catalytic oxidation of toluene at low temperature. J Ind Eng Chem 2012, 18:757-762.
30. Wang G., Zhang L., Zhang J. A review of electrode materials for electrochemical supercapacitors. Chem Soc Rev 2012, 41:797-828.
31. 2 nanosheet array as a stable high-capacitance supercapacitor electrode. J Mater Chem 2013, 1:9809-9813.
32. 2/C supercapacitors. RSC Adv 2014, 4:31416-31423.
33. Ren Z., Lan Y., Wang Y. Aligned carbon nanotubes physics, concepts, fabrication and devices 2013, Springer, Berlin Heidelberg.
34. Zhang L.L., Zhou R., Zhao X. Graphene-based materials as supercapacitor electrodes. J Mater Chem 2010, 20:5983-5992.
35. Zhai Y., Dou Y., Zhao D., Fulvio P.F., Mayes R.T., Dai S. Carbon materials for chemical capacitive energy storage. Adv Mater 2011, 23:4828-4850.
36. 2 on carbon nanotube array grown on carbon fabric. Electrochim Acta 2012, 78:515-523.
37. Raymundo-Piñero E., Khomenko V., Frackowiak E., Béguin F. Performance of manganese oxide/CNTs composites as electrode materials for electrochemical capacitors. J Electrochem Soc 2005, 152:A229.
38. 2-carbon nanotube-textile nanostructures for wearable pseudocapacitors with high mass loading. ACS Nano 2011, 5:8904-8913.
39. Dey N.K., Hong E.M., Choi K.H., Kim Y.D., Lim J.-H., Lee K.H., et al. Growth of carbon nanotubes on carbon fiber by thermal CVD using Ni nanoparticles as catalysts. Proc Eng 2012, 36:556-561.
40. Rahmanian S., Suraya A.R., Zahari R., Zainudin E.S. Synthesis of vertically aligned carbon nanotubes on carbon fiber. Appl Surf Sci 2013, 271:424-428.
41. Zhang Q., Liu J., Sager R., Dai L., Baur J. Hierarchical composites of carbon nanotubes on carbon fiber: influence of growth condition on fiber tensile properties. Compos Sci Technol 2009, 69:594-601.
42. De Resende V.G., Antunes E.F., de Oliveira Lobo A., Oliveira D.A.L., Trava-Airoldi V.J., Corat E.J. Growth of carbon nanotube forests on carbon fibers with an amorphous silicon interface. Carbon 2010, 48:3655-3658.
43. Hu Z.-H., Dong S.-M., Hu J.-B., Wang Z., Lu B., Yang J.-S., et al. Synthesis of carbon nanotubes on carbon fibers by modified chemical vapor deposition. New Carbon Mater 2012, 27:352-361.
44. An F., Lu C., Guo J., He S., Lu H., Yang Y. Preparation of vertically aligned carbon nanotube arrays grown onto carbon fiber fabric and evaluating its wettability on effect of composite. Appl Surf Sci 2011, 258:1069-1076.
45. Zhao T., Kvande I., Yu Y., Ronning M., Holmen A., Chen D. Synthesis of platelet carbon nanofiber/carbon felt composite on in situ generated Ni-Cu nanoparticles. J Phys Chem C 2011, 115:1123-1133.
46. Ghamouss F., Luais E., Thobie-Gautier C., Tessier P.Y., Boujtita M. Argon plasma treatment to enhance the electrochemical reactivity of screen-printed carbon surfaces. Electrochim Acta 2009, 54:3026-3032.
47. Yan B., Qian K., Zhang Y., Xu D. Effects of argon plasma treating on surface morphology and gas ionization property of carbon nanotubes. Physica E 2005, 28:88-92.
48. Groenewoud L., Terlingen J., Engbers G., Feijen J. Removal of pendant groups of vinyl polymers by argon plasma treatment. Langmuir 1999, 15:5396-5402.
49. Tajima S., Komvopoulos K. Surface modification of low-density polyethylene by inductively coupled argon plasma. J Phys Chem B 2005, 109:17623-17629.
50. Tay B.K., Sheeja D., Lau S.P., Guo J.X. Study of surface energy of tetrahedral amorphous carbon films modified in various gas plasma. Diam Relat Mater 2003, 12:2072-2076.
51. 2-based mixed oxides for high performance redox supercapacitors. Electrochem Commun 2004, 6:1004-1008.
52. Lu W., Qu L., Henry K., Dai L. High performance electrochemical capacitors from aligned carbon nanotube electrodes and ionic liquid electrolytes. J Power Sources 2009, 189:1270-1277.
53. Chen C.-M., Dai Y.-M., Huang J.G., Jehng J.-M. Intermetallic catalyst for carbon nanotubes (CNTs) growth by thermal chemical vapor deposition method. Carbon 2006, 44:1808-1820.
54. 2 composites as supercapacitor electrodes. Carbon 2010, 48:3825-3833.
55. Yan J., Wei T., Shao B., Fan Z., Qian W., Zhang M., et al. Preparation of a graphene nanosheet/polyaniline composite with high specific capacitance. Carbon 2010, 48:487-493.
56. Zaldivar R.J., Nokes J.P., Adams P.M., Hammoud K., Kim H.I. Surface functionalization without lattice degradation of highly crystalline nanoscaled carbon materials using a carbon monoxide atmospheric plasma treatment. Carbon 2012, 50:2966-2975.
57. Sing K.S.W., Everett D.H., Haul R.A.W., Moscou L., Pierotti R.A., Rouquerol J., et al. Reporting physisorption data for gas solid systems with special reference to the determination of surface-area and porosity. Pure Appl Chem 1985, 57:603.
58. Peng C., Yan X.-B., Wang R.-T., Lang J.-W., Ou Y.-J., Xue Q.-J. Promising activated carbons derived from waste tea-leaves and their application in high performance supercapacitors electrodes. Electrochim Acta 2013, 87:401-408.
59. Wu F.-C., Tseng R.-L., Juang R.-S. Preparation of highly microporous carbons from fir wood by KOH activation for adsorption of dyes and phenols from water. Sep Purif Technol 2005, 47:10-19.
60. Li M., Li W., Liu S. Hydrothermal synthesis, characterization, and KOH activation of carbon spheres from glucose. Carbohydr Res 2011, 346:999-1004.
61. Xu B., Wu F., Su Y., Cao G., Chen S., Zhou Z., et al. Competitive effect of KOH activation on the electrochemical performances of carbon nanotubes for EDLC: balance between porosity and conductivity. Electrochim Acta 2008, 53:7730-7735.
62. Ryu Z., Zheng J., Wang M., Zhang B. Characterization of pore size distributions on carbonaceous adsorbents by DFT. Carbon 1999, 37:1257-1264.
63. Di Fabio A., Giorgi A., Mastragostino M., Soavi F. Carbon-poly (3-methylthiophene) hybrid supercapacitors. J Electrochem Soc 2001, 148. A845-A50.
64. 2 nanorods hybrid structure. ACS Nano 2011, 6:656-661.
65. 2. ACS Appl Mater Interfaces 2012, 4:2801-2810.
66. Chen W., Rakhi R.B., Hu L., Xie X., Cui Y., Alshareef H.N. High-performance nanostructured supercapacitors on a sponge. Nano Lett 2011, 11:5165-5172.
67. Yu M., Zhai T., Lu X., Chen X., Xie S., Li W., et al. Manganese dioxide nanorod arrays on carbon fabric for flexible solid-state supercapacitors. J Power Sources 2013, 239:64-71.
68. 2 composites for high-performance supercapacitor. Electrochim Acta 2013, 109:587-594.