[1] [1] KIERZEK K，FRACKOWIAK E，LOTA G，et al.Electrochemical capacitors based on highly porous carbons prepared by KOH activation［J］.Electrochimica Acta，2004，49(4): 515-523.

[2] [2] RAYMUNDO-PINERO E，LEROUX F，BEGUIN F.A high-performance carbon for supercapacitors obtained by carbonization of a seaweed biopolymer［J］.Advanced Materials，2006，18(14): 1877-1882.

[3] [3] ZHENG J P，JOW T R.High energy and high power density electrochemical capacitors［J］.Journal of Power Sources，1996，62(2): 155-159.

[4] [4] TOUPIN M，BROUSSE T，BELANGER D.Charge storage mechanism of MnO2 electrode used in aqueous electrochemical capacitor［J］.Chemistry of Materials，2004，16(16): 3184-3190.

[5] [5] RUDGE A，RAISTRICK I，GOTTESFELD S，et al.A study of the electrochemical properties of conducting polymers for application in electrochemical capacitors［J］.Electrochimica Acta，1994，39(2): 273-287.

[6] [6] TALBI H，JUST P E，DAO L H.Electropolymerization of aniline on carbonized polyacrylonitrile aerogel electrodes: applications for supercapacitors［J］.Journal of Applied Electrochemistry，2003，33(6): 465-473.

[7] [7] NOVOSELOV K S，GEIM A K，MOROZOV S V，et al.Electric field effect in atomically thin carbon films［J］.Science，2004，306(5696): 666-669.

[8] [8] LOSURDO M，GIANGREGORIO M M，CAPEZZUTO P，et al.Graphene CVD growth on copper and nickel: role of hydrogen in kinetics and structure［J］.Physical Chemistry Chemical Physics，2011，13(46): 20836-20843.

[9] [9] HU ZHONGAI，MO LIPING，FENG XIAOJUAN，et al.Synthesis and electrochemical capacitance of sheet-like cobalt hydroxide［J］.Materials Chemistry and Physics，2009，114(1): 53-57.

[10] [10] CHI X N，CHANG L，XIE D，et al.Hydrothermal preparation of Co3O4/graphene composite as anode material for lithium-ion batteries［J］.Materials Letters，2013(106): 178-181.

[11] [11] WANG LEI， DONG ZHIHUI，WANG ZHENGGONG，et al.Layered α-Co(OH)2 nanocones as electrode materials for pseudocapacitors: understanding the effect of interlayer space on electrochemical activity［J］.Advanced Functional Materials，2013，23(21): 2758-2764.

[12] [12] ZHAO CUIMEI，WANG XIN，WANG SHUMIN，et al.Synthesis of Co(OH)2/graphene/Ni foam nano-electrodes with excellent pseudocapacitive behavior and high cycling stability for supercapacitors［J］.International Jounal of Hydrogen energy，2012，37(16): 11846-11852.

[13] [13] ZHAO DANDAN，ZHOU WENJIA，LI HULIN.Effect of deposition potential and anneal temperature on the hexagonal nanoporous nickel hydroxide films［J］.Chemistry of Materials，2007，19(16): 3882-3891.

[14] [14] ZHOU WENJIA，ZHANG JIN，XUE TONG，et al.Electrodeposition of ordered mesoporous cobalt hydroxide film from lyotropic liquid crystal media for electrochemical capacitors［J］.Journal of Materials Chemistry，2008，18(8): 905-910.

[15] [15] HUANG L，LIU Y，JI L C，et al.Pulsed laser assisted reduction of graphene oxide［J］.Carbon，2011，49(7): 2431-2436.

[16] [16] YE X H，LONG J Y，LIN Z，et al.Direct laser fabrication of large-area and patterned graphene at room temperature［J］.Carbon，2014(68): 784-790.

[17] [17] WANG J N，SHAO R Q，ZHANG Y L，et al.Biomimetic graphene surfaces with superhydrophobicity and iridescence［J］.Chemistry-An Asian Journal，2012，7(2): 301-304.

[18] [18] BORDJIBA T，MOHAMEDI M，DAO L H.New class of carbon-nanotube aerogel electrodes for electrochemical power sources［J］.Advanced Materials，2008，20(4): 815-819.

[19] [19] ZHAO T，JIANG H，MA J.Surfactant-assisted electrochemical deposition of α-cobalt hydroxide for supercapacitors［J］.Journal of Power Sources，2011，196(2): 860-864.

[20] [20] WANG H L，HAO Q L，YANG X J，et al.A nanostructured graphene/polyaniline hybrid material for supercapacitors［J］.Nanoscale，2010，2(10): 2164-2170.

[21] [21] LEE J，SEOK J Y，SON S，et al.High-energy, flexiblemicro-supercapacitor by one-step laser fabrication of self-generated nanoporous metal/oxide electrode［J］.Journal of Materials Chemistry A，2017，5(47): 24585-24593.

[22] [22] KONG L B，LIU M，LANG J W，et al.Asymmetric supercapacitor based on loose-packed cobalt hydroxide nanoflake materials and activated carbon［J］.Journal of The Electrochemical Society，2009(156): 1000-1004.

[23] [23] MA CUNLIANG，PENG LI，FENG YAFEI，et al.Polyfurfuryl alcohol spheres template synthesis of 3D porous graphene for high-performance supercapacitor application［J］.Synthetic Metals，2016(220): 227-235.

[24] [24] CHEN TAO，CAI ZHENBO，QIU LONGBIN，et al.Synthesis of aligned carbon nanotube composite fibers with high performances by electrochemical deposition［J］.Journal of Materials Chemistry A，2013(1): 2211-2216.

[25] [25] SUN H，YE Y，LIU J，et al.Pure Ni nanocrystallines anchored on rGO present ultrahigh electrocatalytic activit and stability in methanol oxidation［J］.Chemical Communications，2018，54(13): 1563-1566.

[26] [26] POURMORTAZAVI S M，RAHIMI-NASRABADI M，DAVOUDI-DEHAGHANI A A，et al.Statistical optimization of experimental parameters for synthesis of manganese carbonate and manganese oxide nanoparticles［J］.Materials Research Bulletin，2012，47(4): 1045-1050.

[27] [27] GHODBANE O，PASCAL J L，FAVIER F.Microstructural effects on charge-storage properties in MnO2-based electrochemical supercapacitors［J］.ACS Applied Materials & Interfaces，2009，1(5): 1130-1139.

[29] [29] RUDGE A，DAVEY J，RAISTRICK I，et al.Conducting polymers as active materials in electrochemical capacitors［J］.Journal of Power Sources，1994，47(1-2): 89-107.

[30] [30] ZHOU HAIHUI，CHEN HONG，LUO SHENGLIAN，et al.The effect of the poly aniline morphology on the performance of poly aniline supercapacitors［J］.Journal of Solid State Electrochemistry，2005，9(8): 574-580.

[31] [31] LAFORGUE A，SIMON P，SARRAZIN C，et al.Polythiophene-based supercapacitors［J］.Journal of Power Sources，1999，80(1-2): 142-148.

[32] [32] KWANG S R，KWANG M K，PARK N G，et al.Symmetric redox supercapacitor with conducting poly aniline electrodes［J］.Journal of Power Source，2002，103(2): 305-309.

[33] [33] ZHAO J Q，LIU Y Y，YU Y L.Dual-responsive inverse opal films based on a crosslinked liquid crystal polymer containing azobenzene［J］.Journal of Materials Chemistry C，2014，2(48): 10262-10267.

[34] [34] FAN L Z，HU Y S，MAIER J，et al.High electroactivity of polyaniline in supercapacitors by using a hierarchically porous carbon monolith as a support［J］.Advanced Functional Materials， 2007，17(16): 3083-3087.

[37] [37] HUANG L，LIU Y，JI L C，et al.Pulsed laser assisted reduction of graphene oxide［J］.Carbon，2011，49(7): 2431-2436.

[38] [38] YE X H，LONG J Y，LIN Z，et al.Direct laser fabrication of large-area and patterned graphene at room temperature［J］.Carbon，2014(68): 784-790.

[39] [39] DARVISHI S，CUBAUD T，LONGTIN J P.Ultrafast laser machining of tapered microchannels in glass and PDMS［J］.Optics and Lasers in Engineering，2012，50(2): 210-214.

[40] [40] LUO S，HOANG P T，LIU T.Direct laser writing for creating porous graphitic structures and their use for flexible and highly sensitive sensor and sensor arrays［J］.Carbon，2016(96): 522-531.

[41] [41] HWANG D J，KUK S，WANG Z，et al.Laser scribing of CIGS thin-film solar cell on flexible substrate［J］.Applied Physics A，2016，123(1): 55.

[42] [42] DU Q F，AI J，QIN Z L，et al.Fabrication of superhydrophobic/super hydrophilic patterns on polyimide surface by ultraviolet laser direct texturing［J］.Journal of Materials Processing Technology，2018(251): 188-196.

[43] [43] TILIAKOS A，CEAUS C，IORDACHE S M，et al.Morphic transitions of nanocarbons via laser pyrolysis of polyimide film［J］.Journal of Analytica and Applied Pyrolysis，2016(121): 275-286.

[44] [44] MORACZEWSKI K，MRZ W，BUDNER B，et al.Laser modification of polylactide surface layer prior autocatalytic metallization［J］.Surface and Coatings Technology，2016(304): 68-75.

[45] [45] LIN J，PENG Z，LIU Y，et al.Laser-Induced porous graphene films from commercial polymers［J］.Nature Communications，2014(5): 1-8.

[48] [48] NIU Z Q，ZHANG L，LIU L L，et al.All-solid-state flexible ultrathin micro-supercapacitors based on graphene［J］.Advanced Materials，2013，25(29): 4035-4042.

[49] [49] BEIDAGHI M，WANG C L.Micro-supercapacitors based on interdigital electrodes of reduced graphene oxide and carbon nanotube composites with ultrahigh power handling performance［J］.Advanced Functional Materials，2012，22(21): 4501-4510.

[50] [50] KIM S K， KOO H J，LEE A，et al.Selective wetting-induced micro-electrode patterning for flexible micro-supercapacitors［J］.Advanced Materials，2014，26(30): 5108-5112.

[51] [51] SONG B，LI L Y，LIN Z Y，et al.Water-dispersible graphene/polyaniline composites for flexible micro-supercapacitors with high energy densities［J］.Nano Energy，2015(16): 470-478.

[52] [52] WU Z S，PARVEZ K，FENG X L，et al.Graphene-based in-plane micro-supercapacitors with high power and energy densities［J］.Nature Communications，2013(4): 1-8.

[53] [53] LIU L，YE D，YU Y，et al.Carbon-based flexible micro-supercapacitor fabrication via mask-free ambient micro-plasma-jet etching［J］.Carbon，2017(111): 121-127.

[54] [54] SONG Y，CHEN X X，ZHANG J X，et al.Freestanding micro-supercapacitor with interdigital electrodes for low-power electronic systems［J］.Journal of Microelectromechanical Systems，2017，26(5): 1055-1062.

[55] [55] YAN H，CHEN Z H，ZHENG Y，et al.A high-mobility electron-transporting polymer for printed transistors［J］.Nature，2009，457(7230): 679-686.

[56] [56] LEE H M，LEE H B，JUNG D S，et al.Solution processed aluminum paper for flexible electronics［J］.Langmuir，2012，28(36): 13127-13135.

[57] [57] CHEN P C，CHEN H T，QIU J，et al.Inkjet printing of single-walled carbon nanotube/RuO2 nanowire supercapacitors on cloth fabrics and flexible substrates［J］.Nano Research，2010，3(8): 594-603.

[58] [58] QI D P，LIU Y，LIU Z Y，et al.Design of architectures and materials in in-plane micro-supercapacitors: current status and future challenges［J］.Advanced Materials，2017，29(5): 1-19.

[59] [59] ZHANG L，DEARMOND D，ALVAREZ N T，et al.Flexible micro-supercapacitor based on graphene with 3d structure［J］.Small，2017，13(10): 1603114.

[60] [60] SHI L，WANG Y，ZOU P C，et al.Laser processed micro-supercapacitors based on carbon nanotubes/manganese dioxide nanosheets composite with excellent electrochemical performance and aesthetic property［J］.Chinese Chemical Letters，2018，29(4): 592-595.

[61] [61] PAENG D，LEE D，YEO J，et al.Laser-induced reductive sintering of nickel oxide nanoparticles under ambient conditions［J］.The Journal of Physical Chemistry C，2015，119(11): 6363-6372.

[62] [62] PERELAER J，DE GANS B J，SCHUBERT U S.Ink-jet printing and microwave sintering of conductive silver tracks［J］.Advanced Materials，2006，18(16): 2101-2104.

[63] [63] CHUNG J W，KO S B，BIERI N R，et al.Conductor microstructures by laser curing of printed gold nanoparticle ink［J］.Applied Physics Letters，2004，84(5): 801-803.

[64] [64] HONG S，YEO J，KIM G，et al.Nonvacuum, maskless fabrication of a flexible metal grid transparent conductor by low-temperature selective laser sintering of nanoparticle ink［J］.ACS Nano，2013，7(6): 5024-5031.

[65] [65] KO S H，PAN H，GRIGOROPOULOS C P，et al.Air stable high resolution organic transistors by selective laser sintering of ink-jet printed metal nanoparticles［J］.Applied Physics Letters，2007，90(14): 141103.

[66] [66] YEO J，HONG S，LEE D，et al.Next generation non-vacuum，mask less, low temperature nanoparticle ink laser digital direct metal patterning for a large area flexible electronics［J］.PLoS One，2012，7(8): e42315.

[67] [67] KO S H，CHUNG J， PAN H， et al.Fabrication of multilayer passive and active electric components on polymer using inkjet printing and low temperature laser processing［J］.Sensors and Actuators A: Physical，2007，134(1): 161-168.

[68] [68] CHENG K，YANG M H，CHIU W W W，et al.Ink-jet printing, self-assembled polyelectrolytes, and electroless plating: low cost fabrication of circuits on a flexible substrate at room temperature［J］.Macromolecular Rapid Communications，2005，26(4): 247-264.

[69] [69] CHIOLERIO A，MACCIONI G，MARTINO P，et al.Inkjet printing and low power laser annealing of silver nanoparticle traces for the realization of low resistivity lines for flexible electronics［J］.Microelectronic Engineering，2011，88(8): 2481-2483.

[70] [70] CAI J，WATANABE A，LV C.Laser direct writing of carbon/Au composite electrodes for high-performance micro-supercapacitors［C］//Conference on Laser-based Micro-and Nanoprocessing XI: International Society for Optics and Photonics，SPIE， 2017(10092): 1-8.