Graphene-based materials for flexible electrochemical energy storage

International Journal of Energy Research

Volumn 39, Issue 6, 2015, Pages 727-740

  Mao, Min ^a   Hu, Junyan ^a   Liu, Hongtao ^a  

^a CENTRAL SOUTH UNIVERSITY   (China)

Author keywords

Flexible energy storage; Graphene electrochemistry; Lithium ion battery; Supercapacitor

Indexed keywords

CHEMICAL STABILITY; ENERGY CONVERSION; ENERGY STORAGE; GRAPHENE; GRAPHENE DEVICES; NATURAL RESOURCES; NETWORK LAYERS; RENEWABLE ENERGY RESOURCES; STORAGE (MATERIALS); SUPERCAPACITOR;

ELECTROCHEMICAL ENERGY STORAGE; ELECTROCHEMICAL ENERGY STORAGE DEVICES; ENERGY CONVERSION AND STORAGES; ENERGY STORAGE AND CONVERSIONS; HIGH SPECIFIC SURFACE AREA; MECHANICAL FLEXIBILITY; RENEWABLE ENERGY SOURCE; USE OF RENEWABLE ENERGIES;

LITHIUM-ION BATTERIES;

EID: 84926420333     PISSN: 0363907X     EISSN: 1099114X     Source Type: Journal    
DOI: 10.1002/er.3256     Document Type: Review

References (99)

1. Arico AS, Bruce P, Scrosati B, Tarascon JM, Van Schalkwijk W. Nanostructured materials for advanced energy conversion and storage devices. Nature Materials 2005; 4:366-377.
2. Gogotsi Y, Simon P. True performance metrics in electrochemical energy storage. Science 2011; 334:917-918.
3. Sun YQ, Wu QO, Shi GQ. Graphene based new energy materials. Energy & Environmental Science 2011; 4:1113-1132.
4. Liang MH, Luo B, Zhi LJ. Application of graphene and graphene-based materials in clean energy-related devices. International Journal of Energy Research 2009; 33:1161-1170.
5. Simon P, Gogotsi Y. Materials for electrochemical capacitors. Nature Materials 2008; 7:845-854.
6. Dunn B, Kamath H, Tarascon JM. Electrical energy storage for the grid: a battery of choices. Science 2011; 334:928-935.
7. Wu Q, Sun YQ, Bai H, Shi GQ. High-performance supercapacitor electrodes based on graphene hydrogels modified with 2-aminoanthraquinone moieties. Physical Chemistry Chemical Physics 2011; 13:11193-11198.
8. Sun YQ, Wu QO, Xu YX, Bai H, Li C, Shi GQ. Highly conductive and flexible mesoporous graphitic films prepared by graphitizing the composites of graphene oxide and nanodiamond. Journal of Materials Chemistry 2011; 21:7154-7160.
9. Sun YQ, Wu Q, Shi GQ. Supercapacitors based on self-assembled graphene organogel. Physical Chemistry Chemical Physics 2011; 13:17249-17254.
10. Xu CH, Xu BH, Gu Y, Xiong ZG, Sun J, Zhao XS. Graphene-based electrodes for electrochemical energy storage. Energy & Environmental Science 2013; 6:1388-1414.
11. Mahmood N, Zhang CZ, Yin H, Hou YL. Graphene-based nanocomposites for energy storage and conversion in lithium batteries, supercapacitors and fuel cells. Journal of Materials Chemistry A 2014; 2:15-32.
12. Zhu J, Yang D, Yin Z, Yan Q, Zhang H. Graphene and graphene-based materials for energy storage applications. Small. 2014; 10:3480-3498.
13. Wang GP, Zhang L, Zhang JJ. A review of electrode materials for electrochemical supercapacitors. Chemical Society Reviews 2012; 41:797-828.
14. Lu XM, Xia YN. Electronic materials - buckling down for flexible electronics. Nature Nanotechnology 2006; 1:163-164.
15. Rogers JA, Huang YG. A curvy, stretchy future for electronics. Proceedings of the National Academy of Sciences of the United States of America 2009; 106:10875-10876.
16. Liu C, Li F, Ma LP, Cheng HM. Advanced materials for energy storage. Advanced Materials 2010; 22:E28-E62.
17. Chen PC, Shen GZ, Shi Y, Chen HT, Zhou CW. Preparation and characterization of flexible asymmetric supercapacitors based on transition-metal-oxide nanowire/single-walled carbon nanotube hybrid thin-film electrodes. Acs Nano 2010; 4:4403-4411.
18. Pushparaj VL, Shaijumon MM, Kumar A, Murugesan S, Ci L, Vajtai R, Linhardt RJ, Nalamasu O, Ajayan PM. Flexible energy storage devices based on nanocomposite paper. Proceedings of the National Academy of Sciences of the United States of America 2007; 104:13574-13577.
19. 2 and ZnO on dye-sensitized solar cell performance. International Journal of Energy Research 2014; 38:674-682.
20. Allen MJ, Tung VC, Kaner RB. Honeycomb carbon: a review of graphene. Chemical Reviews 2010; 110:132-145.
21. Yu GH, Hu LB, Vosgueritchian M, Wang HL, Xie X, McDonough JR, Cui X, Cui Y, Bao ZN. Solution-processed graphene/MnO2 nanostructured textiles for high-performance electrochemical capacitors. Nano Letters 2011; 11:2905-2911.
22. Meng YN, Zhao Y, Hu CG, Cheng HH, Hu Y, Zhang ZP, Shi GQ, Qu LG. All-graphene core-sheath microfibers for all-solid-state, stretchable fibriform supercapacitors and wearable electronic textiles. Advanced Materials 2013; 25:2326-2331.
23. Li YR, Sheng KX, Yuan WJ, Shi GQ. A high-performance flexible fibre-shaped electrochemical capacitor based on electrochemically reduced graphene oxide. Chemical Communications 2013; 49:291-293.
24. Li XM, Zhao TS, Wang KL, Yang Y, Wei JQ, Kang FY, Wu DH, Zhu HW. Directly drawing self-assembled, porous, and monolithic graphene fiber from chemical vapor deposition grown graphene film and its electrochemical properties. Langmuir 2011; 27:12164-12171.
25. Zhang LL, Zhao X, Stoller MD, Zhu YW, Ji HX, Murali S, Wu YP, Perales S, Clevenger B, Ruoff RS. Highly conductive and porous activated reduced graphene oxide films for high-power supercapacitors. Nano Letters 2012; 12:1806-1812.
26. Wang GK, Sun X, Lu FY, Sun HT, Yu MP, Jiang WL, Liu CS, Lian J. Flexible pillared graphene-paper electrodes for high-performance electrochemical supercapacitors. Small 2012; 8:452-459.
27. Liu F, Song SY, Xue DF, Zhang HJ. Folded structured graphene paper for high performance electrode materials. Advanced Materials 2012; 24:1089-1094.
28. El-Kady MF, Strong V, Dubin S, Kaner RB. Laser scribing of high-performance and flexible graphene-based electrochemical capacitors. Science 2012; 335:1326-1330.
29. Choi BG, Hong J, Hong WH, Hammond PT, Park H. Facilitated ion transport in all-solid-state flexible supercapacitors. Acs Nano 2011; 5:7205-7213.
30. Choi BG, Huh YS, Hong WH, Erickson D, Park HS. Electroactive nanoparticle directed assembly of functionalized graphene nanosheets into hierarchical structures with hybrid compositions for flexible supercapacitors. Nanoscale 2013; 5:3976-3981.
31. Kim TY, Lee HW, Stoller M, Dreyer DR, Bielawski CW, Ruoff RS, Suh KS. High-performance supercapacitors based on poly(ionic liquid)-modified graphene electrodes. Acs Nano 2011; 5:436-442.
32. Lu XJ, Dou H, Yuan CZ, Yang SD, Hao L, Zhang F, Shen LF, Zhang LJ, Zhang XG. Polypyrrole/carbon nanotube nanocomposite enhanced the electrochemical capacitance of flexible graphene film for supercapacitors. Journal of Power Sources 2012; 197:319-324.
33. Peng LW, Feng YY, Lv P, Lei D, Shen YT, Li Y, Feng W. Transparent, conductive, and flexible multiwalled carbon nanotube/graphene hybrid electrodes with two three-dimensional microstructures. Journal of Physical Chemistry C 2012; 116:4970-4798.
34. Lee SH, Kim HW, Hwang JO, Lee WJ, Kwon J, Bielawski CW, Ruoff RS, Kim SO. Three-dimensional self-assembly of graphene oxide platelets into mechanically flexible macroporous carbon films. Angewandte Chemie-International Edition 2010; 49:10084-10088.
35. Jin Y, Chen HY, Chen MH, Liu N, Li QW. Graphene-patched CNT/MnO2 nanocomposite papers for the electrode of high-performance flexible asymmetric supercapacitors. Acs Applied Materials & Interfaces 2013; 5:3408-3416.
36. Sawangphruk M, Srimuk P, Chiochan P, Krittayavathananon A, Luanwuthi S, Limtrakul J. High-performance supercapacitor of manganese oxide/reduced graphene oxide nanocomposite coated on flexible carbon fiber paper. Carbon 2013; 60:109-116.
37. Liu WW, Yan XB, Lang JW, Peng C, Xue QJ. Flexible and conductive nanocomposite electrode based on graphene sheets and cotton cloth for supercapacitor. Journal of Materials Chemistry 2012; 22:17245-17253.
38. Weng Z, Su Y, Wang DW, Li F, Du JH, Cheng HM. Graphene-cellulose paper flexible supercapacitors. Advanced Energy Materials 2011; 1:917-922.
39. Mao M, Chen SZ, He P, Zhang HL, Liu HT. Facile and economical mass production of graphene dispersions and flakes. Journal of Materials Chemistry 2014; 2:4132-4135.
40. 2SO4 porous gel electrolytes. Journal of Power Sources 2014; 266:488-495.
41. 2O/graphene composite. Journal of Materials Chemistry A 2014; 2:10876-10881.
42. Shi JL, Du WC, Yin YX, Guo YG, Wan LJ. Hydrothermal reduction of three-dimensional graphene oxide for binder-free flexible supercapacitors. Journal of Materials Chemistry A 2014; 2:10830-10834.
43. Huang L, Li C, Shi G. High-performance and flexible electrochemical capacitors based on graphene/polymer composite films. Journal of Materials Chemistry A 2014; 2:968-974.
44. Chen ZP, Ren WC, Gao LB, Liu BL, Pei SF, Cheng HM. Three-dimensional flexible and conductive interconnected graphene networks grown by chemical vapour deposition. Nature Materials 2011; 10:424-428.
45. He YM, Chen WJ, Li XD, Zhang ZX, Fu JC, Zhao CH, Xie EQ. Freestanding three-dimensional graphene/MnO2 composite networks as ultra light and flexible supercapacitor electrodes. Acs Nano 2013; 7:174-182.
46. Choi BG, Yang M, Hong WH, Choi JW, Huh YS. 3D macroporous graphene frameworks for supercapacitors with high energy and power densities. Acs Nano 2012; 6:4020-4028.
47. Ju HF, Song WL, Fan LZ. Rational design of graphene/porous carbon aerogels for high-performance flexible all-solid-state supercapacitors. Journal of Materials Chemistry A 2014; 2:10895-10903.
48. Xu YX, Sheng KX, Li C, Shi GQ. Self-assembled graphene hydrogel via a one-step hydrothermal process. Acs Nano 2010; 4:4324-4330.
49. Zhang L, Shi GQ. Preparation of highly conductive graphene hydrogels for fabricating supercapacitors with high rate capability. Journal of Physical Chemistry C 2011; 115:17206-17212.
50. Zhao Y, Liu J, Hu Y, Cheng HH, Hu CG, Jiang CC, Jiang L, Cao AY, Qu LT. Highly compression-tolerant supercapacitor based on polypyrrole-mediated graphene foam Electrodes. Advanced Materials 2013; 25:591-595.
51. Bose S, Kuila T, Mishra AK, Kim NH, Lee JH. Preparation of non-covalently functionalized graphene using 9-anthracene carboxylic acid. Nanotechnology 2011; 22:405603.
52. An XH, Simmons TJ, Shah R, Wolfe C, Lewis KM, Washington M, Nayak SK, Talapatra S, Kar S. Stable aqueous dispersions of noncovalently functionalized graphene from graphite and their multifunctional high-performance applications. Nano letters 2010; 10:4295-4301.
53. Kuila T, Bose S, Mishra AK, Khanra P, Kim NH, Lee JH. Chemical functionalization of graphene and its applications. Progress in Materials Science 2012; 57:1061-1105.
54. Chang H, Wu H. Graphene-based nanocomposites: preparation, functionalization, and energy and environmental applications. Energy & Environmental Science 2013; 6:3483.
55. Georgakilas V, Otyepka M, Bourlinos AB, Chandra V, Kim N, Kemp KC, Hobza P, Zboril R, Kim KS. Functionalization of graphene: covalent and non-covalent approaches, derivatives and applications. Chemical reviews 2012; 112:6156-6214.
56. Yoo JJ, Balakrishnan K, Huang JS, Meunier V, Sumpter BG, Srivastava A, Conway M, Reddy ALM, Yu J, Vajtai R, Ajayan PM. Ultrathin planar graphene supercapacitors. Nano letters 2011; 11:1423-1427.
57. Park J, Yan MD. Covalent functionalization of graphene with reactive intermediates. Accounts of Chemical Research 2013; 46:181-189.
58. Brownson DAC, Banks CE. Fabricating graphene supercapacitors: highlighting the impact of surfactants and moieties. Chemical Communications 2012; 48:1425-1427.
59. Ai W, Zhou WW, Du ZZ, Du YP, Zhang H, Jia XT, Xie LH, Yi MD, Yu T, Huang W. Benzoxazole and benzimidazole heterocycle-grafted graphene for high-performance supercapacitor electrodes. Journal of Materials Chemistry 2012; 22:23439-23446.
60. Xu YX, Lin ZY, Huang XQ, Wang Y, Huang Y, Duan XF. Functionalized graphene hydrogel-based high-performance supercapacitors. Advanced Materials 2013; 25:5779-5784.
61. Ju S, Li JF, Liu J, Chen PC, Ha YG, Ishikawa F, Chang HK, Zhou CW, Facchetti A, Janes DB, Marks TJ. Transparent active matrix organic light-emitting diode displays driven by nanowire transistor circuitry. Nano Letters 2008; 8:997-1004.
62. Guler MO, Cevher O, Cetinkaya T, Tocoglu U, Akbulut H. Nanocomposite anodes for lithium-ion batteries based on Sno(2) on multiwalled carbon nanotubes. International Journal of Energy Research 2014; 38:487-498.
63. Pushparaj VL, Shaijumon MM, Kumar A, Murugesan S, Ci L, Vajtai R, Linhardt RJ, Nalamasu O, Ajayan PM. Flexible energy storage devices based on nanocomposite paper. Proceedings of the National Academy of Sciences 2007; 104:13574-13577.
64. Zhao X, Hayner CM, Kung MC, Kung HH. Flexible holey graphene paper electrodes with enhanced rate capability for energy storage applications. Acs Nano 2011; 5:8739-8749.
65. Mukherjee R, Thomas AV, Krishnamurthy A, Koratkar N. Photothermally reduced graphene as high-power anodes for lithium-ion batteries. Acs Nano 2012; 6:7867-7878.
66. Hu YH, Li XF, Geng DS, Cai M, Li RY, Sun XL. Influence of paper thickness on the electrochemical performances of graphene papers as an anode for lithium ion batteries. Electrochimica Acta 2013; 91:227-233.
67. Abouimrane A, Compton OC, Amine K, Nguyen ST. Non-annealed graphene paper as a binder-free anode for lithium-ion batteries. Journal of Physical Chemistry C. 2010; 114:12800-12804.
68. Liu SY, Chen K, Fu Y, Yu SY, Bao ZH. Reduced graphene oxide paper by supercritical ethanol treatment and its electrochemical properties. Applied Surface Science 2012; 258:5299-5303.
69. Ning G, Xu C, Cao Y, Zhu X, Jiang Z, Fan Z, Qian W, Wei F, Gao J. Chemical vapor deposition derived flexible graphene paper and its application as high performance anodes for lithium rechargeable batteries. Journal of Materials Chemistry A. 2013; 1:408-414.
70. Lee SH, Seo SD, Park KS, Shim HW, Kim DW. Synthesis of graphene nanosheets by the electrolytic exfoliation of graphite and their direct assembly for lithium ion battery anodes. Materials Chemistry and Physics 2012; 135:309-316.
71. Hu Y, Li X, Wang J, Li R, Sun X. Free-standing graphene-carbon nanotube hybrid papers used as current collector and binder free anodes for lithium ion batteries. Journal of Power Sources 2013; 237:41-46.
72. Kang YR, Li YL, Hou F, Wen YY, Su D. Fabrication of electric papers of graphene nanosheet shelled cellulose fibres by dispersion and infiltration as flexible electrodes for energy storage. Nanoscale 2012; 4:3248-3253.
73. 2 nanocomposites paper for Li-ion battery. ACS applied materials & interfaces 2012; 4:5742-5748.
74. 2 hybrid paper for use as lithium ion battery anode materials. Carbon 2013; 51:322-326.
75. 2/graphene/PVDF films as anode materials for lithium-ion batteries. Applied Surface Science 2012; 263:54-57.
76. Liu Y, Wang W, Gu L, Wang Y, Ying Y, Mao Y. Flexible CuO nanosheets/reduced-graphene oxide composite paper: binder-free anode for high-performance lithium-ion batteries. ACS applied materials & interfaces 2013; 5:9850-9855.
77. Wang R, Xu C, Sun J, Gao L, Lin C. Flexible free-standing hollow Fe3O4/graphene hybrid films for lithium-ion batteries. Journal of Materials Chemistry A 2013; 1:1794-1800.
78. Huang X, Sun B, Chen S, Wang G. Self-assembling synthesis of free-standing nanoporous graphene-transition-metal oxide flexible electrodes for high-performance lithium-ion batteries and supercapacitors. Chemistry, an Asian journal 2014; 9:206-211.
79. 4 fibers for high-performance lithium-ion batteries. ACS applied materials & interfaces 2013; 5:997-1002.
80. 2 nanotube as anode for lithium ion batteries. The Journal of Physical Chemistry Letters 2011; 2:1855-1860.
81. Zhang M, Yan F, Tang X, Li Q, Wang T, Cao G. Flexible CoO-graphene-carbon nanofiber mats as binder-free anodes for lithium-ion batteries with superior rate capacity and cyclic stability. Journal of Materials Chemistry A 2014; 2:5890-5897.
82. 2 nanoparticle decorated graphene flexible films as high-performance anode materials for lithium-ion batteries. Journal of Materials Chemistry A 2014; 2:4598-4604.
83. Dai Y, Cai S, Yang W, Gao L, Tang W, Xie J. Fabrication of self-binding noble metal/flexible graphene composite paper. Carbon 2012; 50:4648-4654.
84. Liu YT, Zhu XD, Duan ZQ, Xie XM. Flexible and robust MoS2-graphene hybrid paper cross-linked by a polymer ligand: a high-performance anode material for thin film lithium-ion batteries. Chemical Communication 2013; 49:10305-10307.
85. Sun F, Huang K, Qi X, Gao T, Liu Y, Zou X. A rationally designed composite of alternating strata of Si nanoparticles and graphene: a high-performance lithium-ion battery anode. Nanoscale 2013; 5:8586-8592.
86. Wang C, Chui YS, Ma R, Wong T, Ren JG, Wu QH, Chen XF, Zhang WJ. A three-dimensional graphene scaffold supported thin film silicon anode for lithium-ion batteries. Journal of Materials Chemistry A. 2013; 1:10092-10098.
87. Wang JZ, Zhong C, Chou SL, Liu HK. Flexible free-standing graphene-silicon composite film for lithium-ion batteries. Electrochemistry Communications 2010; 12:1467-1470.
88. Wang B, Li X, Zhang X, Luo B, Jin M, Liang M, Dayeh SA, Picraux ST, Zhi LJ. Adaptable silicon-carbon nanocables sandwiched between reduced graphene oxide sheets as lithium ion battery anodes. ACS Nano 2013; 7:1437-1445.
89. Tang H, Tu JP, Liu XY, Zhang YJ, Huang S, Li WZ, Wang XL, Gu CD. Self-assembly of Si/honeycomb reduced graphene oxide composite film as a binder-free and flexible anode for Li-ion batteries. Journal of Materials Chemistry A 2014; 2:5834-5840.
90. Kucinskis G, Bajars G, Kleperis J. Graphene in lithium ion battery cathode materials: a review. Journal of Power Sources 2013; 240:66-79.
91. Ha SH, Jeong YS, Lee YJ. Free standing reduced graphene oxide film cathodes for lithium ion batteries. ACS applied materials & interfaces 2013; 5:12295-12303.
92. Wang C, Li D, Too CO, Wallace GG. Electrochemical properties of graphene paper electrodes used in lithium batteries. Chemistry of Materials 2009; 21:2604-2606.
93. 4 nanostructures as cathode materials for flexible lithium-ion batteries. Materials Research Bulletin 2013; 48:3713-3716.
94. Li N, Chen Z, Ren W, Li F, Cheng H-M. Flexible graphene-based lithium ion batteries with ultrafast charge and discharge rates. Proceedings of the National Academy of Sciences 2012; 109:17360-17365.
95. Gwon H, Kim H-S, Lee KU, Seo D-H, Park YC, Lee Y-S, Ahn BT, Kang K. Flexible energy storage devices based on graphene paper. Energy & Environmental Science 2011; 4:1277-1283.
96. Sun Y, Yang SB, Lv LP, Lieberwirth I, Zhang LC, Ding CX, Chen CH. A composite film of reduced graphene oxide modified vanadium oxide nanoribbons as a free standing cathode material for rechargeable lithium batteries. Journal of Power Sources 2013; 241:168-172.
97. Noerochim L, Wang J-Z, Wexler D, Chao Z, Liu H-K. Rapid synthesis of free-standing MoO3/Graphene films by the microwave hydrothermal method as cathode for bendable lithium batteries. Journal of Power Sources 2013; 228:198-205.
98. Zhao X, Hayner CM, Kung MC, Kung HH. Photothermal-assisted fabrication of iron fluoride-graphene composite paper cathodes for high-energy lithium-ion batteries. Chemical Communication 2012; 48:9909-9911.
99. Wei D, Andrew P, Yang H, Jiang Y, Li F, Shan C, Ruan W, Han D, Niu L, Bower C, Ryhänen C, Rouvala M, Amaratunga GAJ, Ivaska A. Flexible solid state lithium batteries based on graphene inks. Journal of Materials Chemistry 2011; 21:9762-9767.