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Xiulei Ji, Kyu Lee, L. Nazar (2009)
A highly ordered nanostructured carbon-sulphur cathode for lithium-sulphur batteries.Nature materials, 8 6
Min-Sang Song, Sang-Cheol Han, Hyunseok Kim, Jin-ho Kim, Ki-tae Kim, Yong‐Mook Kang, H. Ahn, S. Dou, Jai-Young Lee (2004)
Effects of Nanosized Adsorbing Material on Electrochemical Properties of Sulfur Cathodes for Li/S Secondary BatteriesJournal of The Electrochemical Society, 151
Jiazhao Wang, Jun Chen, K. Konstantinov, Lanling Zhao, S. Ng, Guoxiu Wang, Zaiping Guo, Huakun Liu (2006)
Sulphur-polypyrrole composite positive electrode materials for rechargeable lithium batteriesElectrochimica Acta, 51
Feng Wu, Junzheng Chen, Li Li, Teng Zhao, Renjie Chen (2011)
Improvement of Rate and Cycle Performence by Rapid Polyaniline Coating of a MWCNT/Sulfur CathodeJournal of Physical Chemistry C, 115
Hongxia Wang, Tong Lin, A. Kaynak (2005)
Polypyrrole nanoparticles and dye absorption propertiesSynthetic Metals, 151
Zaiping Guo, Jiazhao Wang, H. Liu, S. Dou (2005)
Study of silicon/polypyrrole composite as anode materials for Li-ion batteriesJournal of Power Sources, 146
Wei Wei, Jiulin Wang, Longjie Zhou, Jun Yang, B. Schumann, Yanna Nuli (2011)
\{CNT\} enhanced sulfur composite cathode material for high rate lithium batteryElectrochemistry Communications, 13
Lichao Yin, Jiulin Wang, Fengjiao Lin, Jun Yang, Yanna Nuli (2012)
Polyacrylonitrile/graphene composite as a precursor to a sulfur-based cathode material for high-rate rechargeable Li–S batteriesEnergy and Environmental Science, 5
R. Singh, Amit Kumar, K. Agarwal, Mahesh Kumar, H. Singh, P. Srivastava, Ramadhar Singh (2012)
DC electrical conduction and morphological behavior of counter anion‐governed genesis of electrochemically synthesized polypyrrole filmsJournal of Polymer Science Part B, 50
X. Liang, Yu Liu, Z. Wen, Lezhi Huang, Xiuya Wang, Hao Zhang (2011)
A nano-structured and highly ordered polypyrrole-sulfur cathode for lithiumsulfur batteriesThe Lancet
Jiajia Chen, Qian Zhang, Yinong Shi, Linlin Qin, Yong Cao, M. Zheng, Q. Dong (2012)
A hierarchical architecture S/MWCNT nanomicrosphere with large pores for lithium sulfur batteries.Physical chemistry chemical physics : PCCP, 14 16
Jiazhao Wang, S. Chew, Zhengwei Zhao, S. Ashraf, D. Wexler, Jun Chen, S. Ng, S. Chou, Huakun Liu (2008)
Sulfur–mesoporous carbon composites in conjunction with a novel ionic liquid electrolyte for lithium rechargeable batteriesCarbon, 46
Kefei Li, Bei Wang, D. Su, Jinsoo Park, H. Ahn, Guoxiu Wang (2012)
Enhance electrochemical performance of lithium sulfur battery through a solution-based processing techniqueJournal of Power Sources, 202
Guoxiu Wang, L. Yang, Yun-bo Chen, Jiazhao Wang, S. Bewlay, H. Liu (2005)
An investigation of polypyrrole-LiFePO4 composite cathode materials for lithium-ion batteriesElectrochimica Acta, 50
D. Chang, S. Lee, Sun-wook Kim, Hee‐Tak Kim (2002)
Binary electrolyte based on tetra(ethylene glycol) dimethyl ether and 1,3-dioxolane for lithium-sulfur batteryJournal of Power Sources, 112
Y. Choi, Youngmin Chung, Chang-Yong Baek, Ki-won Kim, H. Ahn, Jou‐Hyeon Ahn (2008)
Effects of carbon coating on the electrochemical properties of sulfur cathode for lithium/sulfur cellJournal of Power Sources, 184
Yuan Yang, Guihua Yu, J. Cha, Hui Wu, Michael Vosgueritchian, Yan Yao, Zhenan Bao, Yi Cui (2011)
Improving the performance of lithium-sulfur batteries by conductive polymer coating.ACS nano, 5 11
Xiangming He, W. Pu, J. Ren, Li Wang, Jiulin Wang, Changyin Jiang, C. Wan (2007)
Charge/discharge characteristics of sulfur composite cathode materials in rechargeable lithium batteriesElectrochimica Acta, 52
H. Yamin, A. Gorenshtein, J. Penciner, Y. Sternberg, E. Peled (1988)
Lithium Sulfur Battery Oxidation/Reduction Mechanisms of Polysulfides in THF SolutionsJournal of The Electrochemical Society, 135
X. Liang, Z. Wen, Yu Liu, Hao Zhang, Jun Jin, Meifen Wu, Xiangwei Wu (2012)
A composite of sulfur and polypyrrole–multi walled carbon combinatorial nanotube as cathode for Li/S batteryJournal of Power Sources, 206
Jayaprakash Navaneedhakrishnan, Jingguo Shen, Surya Moganty, Alex Corona, L. Archer (2011)
Porous hollow carbon@sulfur composites for high-power lithium-sulfur batteries.Angewandte Chemie, 50 26
Linlin Qiu, Shichao Zhang, Lan Zhang, Mingming Sun, Weikang Wang (2010)
Preparation and enhanced electrochemical properties of nano-sulfur/poly(pyrrole-co-aniline) cathode material for lithium/sulfur batteriesElectrochimica Acta, 55
Jiulin Wang, Jun Yang, Yanna Nuli, R. Holze (2007)
Room temperature Na/S batteries with sulfur composite cathode materialsElectrochemistry Communications, 9
P. Novák, K. Müller, K. Santhanam, O. Haas (1997)
Electrochemically Active Polymers for Rechargeable Batteries.Chemical reviews, 97 1
Xiulei Ji, L. Nazar (2010)
Advances in Li–S batteriesJournal of Materials Chemistry, 20
Jiazhao Wang, Lin Lu, Mohammad Choucair, J. Stride, Xun Xu, Huakun Liu (2011)
Sulfur-graphene composite for rechargeable lithium batteriesThe Lancet
Yongzhu Fu, A. Manthiram (2012)
Orthorhombic Bipyramidal Sulfur Coated with Polypyrrole Nanolayers As a Cathode Material for Lithium–Sulfur BatteriesJournal of Physical Chemistry C, 116
A. Hayashi, T. Ohtomo, Fuminori Mizuno, K. Tadanaga, M. Tatsumisago (2004)
Rechargeable lithium batteries, using sulfur-based cathode materials and Li2S–P2S5 glass-ceramic electrolytesElectrochimica Acta, 50
H. Schneider, A. Garsuch, A. Panchenko, O. Gronwald, N. Janssen, P. Novák (2012)
Influence of different electrode compositions and binder materials on the performance of lithium–sulfur batteriesJournal of Power Sources, 205
H. Ryu, T. Kim, Ki-won Kim, Jou‐Hyeon Ahn, T. Nam, Guoxiu Wang, H. Ahn (2011)
Discharge reaction mechanism of room-temperature sodium–sulfur battery with tetra ethylene glycol dimethyl ether liquid electrolyteJournal of Power Sources, 196
Jiazhao Wang, C. Too, Dezhi Zhou, G. Wallace (2005)
Novel electrode substrates for rechargeable lithium/polypyrrole batteries
J. Shim, K. Striebel, E. Cairns (2002)
The Lithium/Sulfur Rechargeable Cell Effects of Electrode Composition and Solvent on Cell PerformanceJournal of The Electrochemical Society, 149
A novel ternary composite, polypyrrole (PPy)‐coated sulphur–carbon nanotube (S‐CNT), is synthesised by using an in situ, one‐pot method. Firstly, elemental sulfur is loaded into the CNT network by a solution‐based processing technique. Then conducting PPy is coated on the surface of the S‐CNT composite to form the S‐CNT‐PPy ternary composite by carrying out polymerization of the pyrrole monomer in situ. The ternary composite is tested as a cathode for lithium–sulfur batteries. The results show that PPy coating improves significantly the performance of the binary composites (S‐CNT and S‐PPy). The conducting PPy is believed to serve multiple functions in the composite: as a conducting additive, an active material, and an adsorbent and container to confine the polysulfides and prevent them from dissolving into the electrolyte. As a result, PPy coating on the S‐CNT composite enhances its conductivity, capacity and cycling stability. The capacity of S‐CNT‐PPy is about 600 mAh g−1 after 40 cycles, which is much higher than for the S‐CNT composite (430 mAh g−1)
ChemPlusChem – Wiley
Published: Apr 1, 2013
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