Supercapacitors have attracted extensive attention due to their unique features like high power,long cycle life and environment-friendly nature.The most critical factor determining the charge storage of a supercapacitor is the characteristics of the electrode material.Firstly,the mechanism of charge storage in capacitors was introduced.Secondly,several new electrode materials which were expected to obtain high energy density and power density,such as the metal organic frameworks (MOFs),covalent organic frameworks (COFs),MXenes,metal nitrides (MN) and black phosphorus(BP) were introduced in detail.And introduced other emerging electrode materials that were expected to obtain high energy density and power density,as well as the parameters of energy,capacitance,power,cycle performance and rateability of the newly produced symmetric/asymmetric supercapacitors.Study have shown that the covalent organic skeleton electrode materials were expected to become a new generation of cheap,green,feasible,and versatile energy storage devices,and its electrochemical performance still had great room for improvement.The application of MOFs,COFs,MN,BP and new organic electrode materials in supercapacitors in recent years was mainly introduced.Finally,the future development of supercapacitors and the challenges of key technologies were prospected.
[1] Manzano-Agugliaro F,Alcayde A,Montoya F G,et al.Scientific production of renewable energies worldwide:an overview[J].Renewable and Sustainable Energy Reviews,2013,18:134-143.
[2] Hussein A K.Applications of nanotechnology in renewable energies—a comprehensive overview and understanding[J].Renewable and Sustainable Energy Reviews,2015,42:460-476.
[3] Twidell J,Weir T.Renewable energy resources[M].London:Routledge Publishers,2015,15-16.
[4] Li Hongfeng,Han Cuiping,Huang Yan,et al.An extremely safe and wearable solid-state zinc ion battery based on a hierarchical structured polymer electrolyte[J].Energy & Environmental Science,2018,11(4):941-951.
[5] Zhou Tianhong,Lv Wei,Li Jia,et al.Twinborn TiO2-TiN heterostructures enabling smooth trapping-diffusion-conversion of polysulfides towards ultralong life lithium-sulfur batteries[J].Energy & Environmental Science,2017,10(7):1694-1703.
[6] Lu Qingwen,He Yanbing,Yu Qipeng,et al.Dendrite-free,high-rate,long-life lithium metal batteries with a 3D cross-linked network polymer electrolyte[J].Advanced Materials,2017,29(13):1604460-1604468.
[7] Han Cuiping,He Yanbing,Liu Ming,et al.A review of gassing behavior in Li4Ti5O12-based lithium ion batteries[J].Journal of Materials Chemistry A,2017,59(14):6368-6381.
[8] Winter M,Brodd R J.What are batteries,fuel cells,and supercapacitors?[J].Chemical Reviews,2004,104(10):4245-4270.
[9] Simon P,Gogotsi Y.Materials for electrochemical capacitors[J].Nanoscience and Technology,2009:320-329.
[10] Yaghi O M,Li H.Hydrothermal synthesis of a metal-organic framework containing large rectangular channels[J].Journal of The American Chemical Society,1995,117(41):10401-10402.
[11] Mahmood A,Guo W,Tabassum H,et al.Metal-organic framework-based nanomaterials for electrocatalysis[J].Advanced Energy Materials,2016,6(17):1600423-1600440.
[12] Kazemi S H,Hosseinzadeh B,Kazemi H,et al.Facile synthesis of mixed metal-organic frameworks:electrode materials for supercapacitors with excellent areal capacitance and operational stability[J].ACS Applied Materials & Interfaces,2018,10(27):23063-23073.
[13] Wang Rutao,Jin Dongdong,Zhang Yabin,et al.Engineering metal organic framework derived 3D nanostructures for high performance hybrid supercapacitors[J].Journal of Materials Chemistry A,2017,5:292-302.
[14] Cote A P,Benin A I,Ockwig N W,et al.Porous,crystalline,covalent organic frameworks[J].Science,2005,310(5751):1166-1170.
[15] Waller P J,Gandara F,Yaghi O M.Chemistry of covalent organic frameworks[J].Accouts of Chemistry Research,2015,48(12):3053-3063.
[16] Ding Sanyuan,Wang Wei.Covalent organic frameworks (COFs):from design to applications[J].Chemical Society Reviews,2013,42(2):548-568.
[17] Xu Q,Dalapati S,Jiang D E.Charge up in wired covalent organic frameworks[J].ACS Central Science,2016,2(9):586-587.
[18] Halder A,Ghosh M,Khayum M A,et al.Interlayer hydrogen-bonded covalent organic frameworks as high-performance supercapacitors[J].Journal of the American Chemical Society,2018,140(35):10941-10945.
[19] Naguib M,Mochalin V N,Barsoum M W,et al.Two-dimensional materials:25th anniversary article:mxenes:a new family of two-dimensional materials[J].Advanced Materials,2014,26(7):992-1005.
[20] Xie X Q,Kretschmer K,Anasori B,et al.Porous Ti3C2Tx MXene for ultrahigh-rate sodium-ion storage with long cycle life[J].ACS Applied Nano Materials,2018,1(2):505-511.
[21] Yu L Y,Hu L F,Anasori B et al.MXene-bonded activated carbon as a flexible electrode for high-performance supercapacitors[J].ACS Energy Letters,2018,3(7):1597-1603.
[22] Muhammad B S,Huang Y C,Qiu W T,et al.Updates on the development of nanostructured transition metal nitrides for electrochemical energy storage and water splitting[J].Materials Today,2017,20(8):425-451.[23] Zhu Changrong,Yang Peihua,Chao Dongliang,et al.All metal nitrides solid-state asymmetric supercapacitors[J].Advanced Materials,2015,27(31):4566-4571.
[24] Das B,Behm M,Lindbergh G,et al.High performance metal nitrides,MN(M=Cr,Co) nanoparticles for non-aqueous hybrid supercapacitors[J].Advanced Powder Technology,2015,26(3):783-788.
[25] Liu Han,Du Yuchen,Deng Yanxin.Semiconducting black phosphorus:synthesis,transport properties and electronic applications[J].Chemical Society Reviews,2015,44(9):2732-2743.
[26] Li Likai,Yu Yijun,Ye Guojun,et al.Black phosphorus field-effect transistors[J].Nat Nanotechnol,2014,9:372-377.
[27] Sun J,Lee H W,Pasta M,et al.A phosphorene-graphene hybrid material as a high-capacity anode for sodium-ion batteries[J].Natura Nanotechnology,2015,10:980-985.
[28] Hao Chunxue,Yang Bingchao,Wen Fusheng,et al.Flexible all-solid-state supercapacitors based on liquid-exfoliated black-phosphorus nanoflakes[J].Advanced Materials,2016,28(16):3194-3201.
[29] Yang Bingchao,Hao Chunxue,Wen Fusheng,et al.Flexible black-phosphorus nanoflake/carbon nanotube composite paper for high-performance all-solid-state supercapacitors[J].ACS Applied Materials & Interfaces,2017,9(51):44478-44484.
[30] Wu Xingjiang,Xu Yijun,Hu Ying,et al.Microfluidic-spinning construction of blackphosphorus-hybrid microfibres for non-woven fabrics toward a high energy density flexible supercapacitor[J].Nature Communicaion,2018,9:4573-4584.
