Materials Reports 2019, Vol. 33 Issue (Z2): 32-37 |
INORGANIC MATERIALS AND CERAMIC MATRIX COMPOSITES |
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Research Progress in Application of Biomass Based Carbon Aerogel Compositesin Supercapacitors |
KONG Lingyu1, HUANG Huijuan1, YANG Xi2, MA Jianfeng1, SHANG Lili1, LIU Xing’e1
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1 Key Laboratory of Bamboo and Rattan Science and Technology, International Center for Bamboo and Rattan, Beijing 100102; 2 School of Materials Science and Engineering, Central South University of Forestry and Technology, Changsha 410211 |
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Abstract Biomass-based carbon aerogel is environmentally friendly and low cost that not only has the advantages of high stability, good conductivity, large specific surface area and adjustable pore structure, but is also characterized by its stable mechanical properties and good elasticity, and is also an excellent basic material for the preparation of composite materials. In recent years, researchers have developed a series of composites using metal compounds and conducting redox polymers with high specific capacitance, graphene with good electrical conductivity and stable mechanical properties, as well as doping hetero atoms supported on biomass-based carbon aerogel. Moreover, progress has been made in applying these composite materials to supercapacitors. In this paper, the preparation methods of transition metal compounds, conductive polymers, graphene, and doping heteroatoms supported on biomass-based carbon aerogel were reviewed. The advantages and disadvantages of different preparation methods were analyzed. Moreover, the applications of different biomass-based carbon aerogel composites in supercapacitors were summarized. Finally, the problems in the preparation of biomass-based carbon aerogel composites and in the application of supercapacitors were discussed, and the future development trend was prospected.
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Published: 25 November 2019
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Fund:This work was financially supported by the National Key Research and Development Program of China (2017YFD0600804). |
About author:: Lingyu Kong received her B.S. degree in wood science and technology from Anhui Agricultural University in 2017. She is currently pursuing a master’s degree at the International Center for Bamboo and Rattan, Chinese Academy of Forestry. Her main research direction is biomass-based carbon materials. Xing’e Liu received her B.E. degree in Anhui Agricultural University in 1997 and received her Ph.D. degree in wood science and technology from Chinese Academy of Forestry in 2005. She was a postdoctoral fellow at Chinese Academy of Forestry from 2006 to 2007. In 2014, she became a professor at International Center for Bamboo and Rattan. Her current research inte-rests include the structure and properties of bamboo and rattan, and biomass-based carbon material. She has published more than 40 journal papers and participated in the compilation of 3 monographs. |
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1 González A, Goikolea E, Barrena J A, et al. Renewable & Sustainable Energy Reviews,2016,58(2016),1189. 2 Sharma P, Bhatti T S. Energy Conversion and Management,2010,51(12),2901. 3 Francois B, Elzbieta F. 超级电容器:材料、系统及应用,机械工业出版社,2014. 4 Pandolfo A G, Hollenkamp A F. Journal of Power Sources,2006,157(1),11. 5 Wang G P, Zhang L, Zhang J J. Chemical Society Reviews,2012,41,797. 6 Meng Q F, Cai K F, Chen Y X, et al. Nano Energy,2017,36,268. 7 Frackowiak E, Béguin F. Carbon,2001,39(6),937. 8 Zhi M J, Xiang C C, Li J T, et al. Nanoscale,2012,5(1),72. 9 Pekala R W. Journal of Materials Science,1989,24(9),3221. 10 Mayer S T, Pekala R W, Kaschmitter J L. Journal of the Electrochemical Society,1993,140,446. 11 杨喜,刘杏娥,马建锋,等.材料导报:综述篇,2017,31(4),45. 12 Wu X L, Wen T, Guo H L, et al. ACS Nano,2013,7(4),3589. 13 Hu Y J, Xing T, Hao Z, et al. ACS Sustainable Chemistry & Enginee-ring,2017,5(10),8663. 14 Zhang G, Lou X W. Scientific Reports,2013,3(3),1470. 15 Sun M, Tie J J, Cheng G, et al. Journal of Materials Chemistry A,2015,3,1730. 16 Favier F, Lei Y, Fournier C, et al. Microporous & Mesoporous Materials,2007,110(1),167. 17 Wen Y X, Qin T F, Wang Z L, et al. Journal of Alloys and Compounds,2017,699,126. 18 Zhang Y Y, Zuo L Z, Zhang L S, et al. Nano Research,2016,9(9),2747. 19 Lai F L, Miao Y E, Zuo L Z, et al. Small,2016,12(24),3235. 20 Zhang H, Cao G P, Wang Z Y, et al. Nano Letters,2008,8(9),2664. 21 Shen L F, Wang J, Xu G Y, et al. Advanced Energy Materials,2015,5(3),1400977. 22 Ren Y M, Xu Q, Zhang J M, et al. ACS Applied Materials & Interfaces,2014,6(12),9689. 23 Hao P, Zhao Z H, Li L Y, et al. Nanoscale,2015,7(34),14401. 24 郝品.可再生资源制备的碳气凝胶及其复合电极材料的电化学性能研究.博士学位论文,山东大学,2015. 25 Snook G A, Kao P, Best A S. Journal of Power Sources,2011,196(1),1. 26 Hughes M, Chen G Z, Shaffer M S P, et al. Chemistry of Materials,2002,14(4),1610. 27 An H F, Wang Y, Wang X Y, et al. Journal of Solid State Electrochemistry,2010,14(4),651. 28 Yu M, Han Y Y, Yao L, et al. Carbohydrate Polymers,2018,199,555. 29 Hao P, Zhao Z H, Leng Y H, et al. Nano Energy,2015,15,9. 30 Chen L F, Huang Z H, Liang H W, et al.Advanced Functional Materials,2015,24(32),5104. 31 Hu Y J, Tong X, Zhuo H, et al. RSC Advances,2016,6,15788. 32 Paraknowitsch J P, Thomas A. Energy & Environmental Science,2013,6(10),2839. 33 冯晨辰,吴爱民,黄昊. 材料导报:综述篇,2016,30(1),143. 34 Paraknowitsch J P, Thomas A, Antonietti M. Journal of Materials Che-mistry,2010,20,6746. 35 李思明,侯朝霞,王少洪,等.材料导报:综述篇,2014,28(12),40. 36 刘欣欣,王小平,王丽军,等.材料导报:综述篇,2011,25(12),92. 37 Guo C X, Li C M. Energy & Environmental Science,2011,4(11),4504. 38 Zhang K, Zhang L L, Zhao X S, et al. Chemistry of Materials,2010,22(4),1392. 39 Li X, Tang Y, Song J, et al. Carbon,2017,129,236. 40 Wang J, Ran R, Sunarso J, et al. Journal of Power Sources,2017,347,259. 41 Song W L, Li X G, Fan L Z. Energy Storage Materials,2016,3,113. 42 Ji J Y, Li Y, Peng W C, et al. Advanced Materials,2015,27(36),5264. 43 Xia X H, Tu J P, Mai Y J, et al. Journal of Materials Chemistry,2011,21,9319. 44 Qu Q T, Zhang P, Wang B, et al. Journal of Physical Chemistry C,2009,113(31),14020. 45 Yang J Q, Duan X C, Qin Q, et al. Journal of Materials Chemistry A,2013,1(27),7880. 46 Zhang L, Wu H B, Lou X W. Chemical Communications,2012,48(55),6912. 47 Hu C C, Chen J C, Chang K H. Journal of Power Sources,2013,221,128. 48 Zhang L L, Zhao X S. Chemical Society Reviews,2009,38(9),2520. 49 Zeng Y P, Wang L, Wang Z Y, et al. Materials Today Communications,2015,5,70. 50 Hao P, Tian J, Sang Y H, et al. Nanoscale,2016,8(36),16292. 51 Zuo L Z, Fan W, Zhang Y F, et al. Nanoscale,2017,9(13),4445. 52 Zhuo H, Hu Y J, Chen Z H, et al. Carbohydrate Polymers,2019,215,322. 53 Zhang F, Liu T, Zhang J, et al. Carbon,2019,147,451. 54 Du J, Liu L, Hu Z, et al.ACS Sustainable Chemistry & Engineering,2018,6(3),4008. 55 Sahu V, Marichi R B, Singh G, et al. Electrochimica Acta,2017,240,146. 56 Meng Y N, Kai W, Zhang Y J, et al. Advanced Materials,2013,25(48),6985. 57 Ge J, Cheng G H, Chen L W. Nanoscale,2011,3(8),3084. 58 Yan X B, Tai Z X, Chen J T, et al. Nanoscale,2011,3(1),212. 59 Cheng Q, Tang J, Ma J, et al. Journal of Physical Chemistry C,2011,115(47),23584. 60 Wu Z Y, Li C, Liang H W, et al. Angewandte Chemie International Edition,2013,125(10),2997. 61 Chen C J, Song J W, Zhu S Z, et al. Chem,2018,4(3),544. 62 Chen Z H, Peng X W, Zhang X T, et al. Carbohydrate Polymers,2017,170,107. 63 Long C L, Qi D P, Wei T, et al. Advanced Functional Materials,2014,24(25),3953. 64 Zhang Y M, Wang F, Zhu H, et al. Applied Surface Science,2017,426,99. 65 Yang X, Jiang Z H, Fei B H, et al. Electrochimica Acta,2018,282,813. 66 Gao K Z, Shao Z Q, Li J, et al. Journal of Materials Chemistry A,2013,1(1),63. |
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