[1] VU M C, THI THIEU N A, LIM J H, et al. Ultrathin thermally conductive yet electrically insulating exfoliated graphene fluoride film for high performance heat dissipation［J］. Carbon, 2020, 157: 741-749.

[2] LIU Y, DUAN X D, HUANG Y, et al. Two-dimensional transistors beyond graphene and TMDCs［J］. Chemical Society Reviews, 2018, 47(16): 6388-6409.

[3] PARK I J, KIM T I, YOON T, et al. Flexible and transparent graphene electrode architecture with selective defect decoration for organic light-emitting diodes［J］. Advanced Functional Materials, 2018, 28(10): 1704435.

[4] EL-KADY M F, SHAO Y L, KANER R B. Graphene for batteries, supercapacitors and beyond［J］. Nature Reviews Materials, 2016, 1(7): 16033.

[5] YUAN W Y, ZHANG Y N, CHENG L F, et al. The applications of carbon nanotubes and graphene in advanced rechargeable lithium batteries［J］. Journal of Materials Chemistry A, 2016, 4(23): 8932-8951.

[6] JUSTINO C I L, GOMES A R, FREITAS A C, et al. Graphene based sensors and biosensors［J］. TrAC Trends in Analytical Chemistry, 2017, 91: 53-66.

[7] RIAD K B, HOA S V, WOOD-ADAMS P M. Photocuring graphene oxide liquid crystals for high-strength structural materials［J］. ACS Omega, 2022, 7(24): 21192-21198.

[8] LOH K P, TONG S W, WU J S. Graphene and graphene-like molecules: prospects in solar cells［J］. Journal of the American Chemical Society, 2016, 138(4): 1095-1102.

[9] DING J H, ZHAO H R, JI D, et al. Ultrafast molecular sieving through functionalized graphene membranes［J］. Nanoscale, 2019, 11(9): 3896-3904.

[10] LI X Y, QU J K, XIE H W, et al. An electro-deoxidation approach to co-converting antimony oxide/graphene oxide to antimony/graphene composite for sodium-ion battery anode［J］. Electrochimica Acta, 2020, 332: 135501.

[11] HOU Y G, LV S H, LIU L P, et al. High-quality preparation of graphene oxide via the Hummers’ method: understanding the roles of the intercalator, oxidant, and graphite particle size［J］. Ceramics International, 2020, 46(2): 2392-2402.

[12] CASALLAS CAICEDO F M, VERA LPEZ E, AGARWAL A, et al. Synthesis of graphene oxide from graphite by ball milling［J］. Diamond and Related Materials, 2020, 109: 108064.

[13] ROSILLO-LOPEZ M, SALZMANN C G. Detailed investigation into the preparation of graphene oxide by dichromate oxidation［J］. ChemistrySelect, 2018, 3(24): 6972-6978.

[14] GEBREEGZIABHER G G, ASEMAHEGNE A S, AYELE D W, et al. One-step synthesis and characterization of reduced graphene oxide using chemical exfoliation method［J］. Materials Today Chemistry, 2019, 12: 233-239.

[15] BRODIE B C. On the atomic weight of graphite［J］. Proceedings of the Royal Society of London, 1859, 10: 11-12.

[16] STAUDENMAIER L. Verfahren zur darstellung der graphitsure［J］. Berichte Der Deutschen Chemischen Gesellschaft, 1898, 31(2): 1481-1487.

[17] HUMMERS W S, OFFEMAN R E. Preparation of graphitic oxide［J］. Journal of the American Chemical Society, 1958, 80(6): 1339.

[18] DIMIEV A M, EIGLER S. Graphene oxide: fundamentals and applications［M］. Hoboken: Wiley, 2016.

[19] DIMIEV A M, TOUR J M. Mechanism of graphene oxide formation［J］. ACS Nano, 2014, 8(3): 3060-3068.

[20] SEILER S, HALBIG C E, GROTE F, et al. Effect of friction on oxidative graphite intercalation and high-quality graphene formation［J］. Nature Communications, 2018, 9: 836.

[21] HUANG J, ZHAO X, MA C, et al. Preparation of few-layer porous graphene by a soft mechanical method with a short rolling transfer process［J］. ChemPlusChem, 2020, 85(11): 2482-2486.

[22] WANG C, KE F, FAN W, et al. Efficient large-scale preparation of defect-free few-layer graphene using a conjugated ionic liquid as green media and its polyetherimide composite［J］. Composites Science and Technology, 2018, 157: 144-151.

[23] ZHANG Y, XU Y L. Simultaneous electrochemical dual-electrode exfoliation of graphite toward scalable production of high-quality graphene［J］. Advanced Functional Materials, 2019, 29(37): 1902171.

[24] LIU N, LUO F, WU H X, et al. One-step ionic-liquid-assisted electrochemical synthesis of ionic-liquid-functionalized graphene sheets directly from graphite［J］. Advanced Functional Materials, 2008, 18(10): 1518-1525.

[26] SHARMA V K. Potassium ferrate(VI): an environmentally friendly oxidant［J］. Advances in Environmental Research, 2002, 6(2): 143-156.

[27] SHARMA V K. Ferrate(VI) and ferrate(V) oxidation of organic compounds: kinetics and mechanism［J］. Coordination Chemistry Reviews, 2013, 257(2): 495-510.

[28] MAO W Q, WANG J M, XU Z H, et al. Effects of the oxidation treatment with K2FeO4 on the physical properties and electrochemical performance of a natural graphite as electrode material for lithium ion batteries［J］. Electrochemistry Communications, 2006, 8(8): 1326-1330.

[29] PENG L, XU Z, LIU Z, et al. An iron-based green approach to 1-h production of single-layer graphene oxide［J］. Nature Communications, 2015, 6: 5716.

[30] SOFER Z, LUXA J, JANKOVSK O, et al. Synthesis of graphene oxide by oxidation of graphite with ferrate(VI) compounds: myth or reality?［J］. Angewandte Chemie International Edition, 2016, 55(39): 11965-11969.

[31] YU C, WANG C F, CHEN S. Facile access to graphene oxide from ferro-induced oxidation［J］. Scientific Reports, 2016, 6: 17071.

[32] YU H T, ZHANG B W, BULIN C K, et al. High-efficient synthesis of graphene oxide based on improved hummers method［J］. Scientific Reports, 2016, 6: 36143.

[33] ZHANG Z Y, XU X C. Nondestructive covalent functionalization of carbon nanotubes by selective oxidation of the original defects with K2FeO4［J］. Applied Surface Science, 2015, 346: 520-527.

[35] DIMIEV A M, BACHILO S M, SAITO R, et al. Reversible formation of ammonium persulfate/sulfuric acid graphite intercalation compounds and their peculiar Raman spectra［J］. ACS Nano, 2012, 6(9): 7842-7849.

[36] LIU Y H, WU X N, TIAN Y X, et al. Largely enhanced oxidation of graphite flakes via ammonium persulfate-assisted gas expansion for the preparation of graphene oxide sheets［J］. Carbon, 2019, 146: 618-626.

[37] ZHENG H, CHENG Y S, ZHAO R R, et al. An improved strategy to synthesize graphite oxide with controllable interlayer spacing as coatings for anticorrosion application［J］. Journal of Applied Polymer Science, 2021, 138(6): 49823.

[38] LIU T, ZHANG R J, ZHANG X S, et al. One-step room-temperature preparation of expanded graphite［J］. Carbon, 2017, 119: 544-547.

[40] KANG F Y, LENG Y, ZHANG T Y. Influences of H2O2 on synthesis of H2SO4-GICs［J］. Journal of Physics and Chemistry of Solids, 1996, 57(6/7/8): 889-892.

[42] HUANG J D, TANG Q Q, LIAO W B, et al. Green preparation of expandable graphite and its application in flame-resistance polymer elastomer［J］. Industrial & Engineering Chemistry Research, 2017, 56(18): 5253-5261.

[43] CHEN X B, TIAN F Y, PERSSON C, et al. Interlayer interactions in graphites［J］. Scientific Reports, 2013, 3: 3046.

[44] DIMIEV A M, CERIOTTI G, BEHABTU N, et al. Direct real-time monitoring of stage transitions in graphite intercalation compounds［J］. ACS Nano, 2013, 7(3): 2773-2780.

[50] HU Y, SU M, XIE X, et al. Few-layer graphene oxide with high yield via efficient surfactant-assisted exfoliation of mildly-oxidized graphite［J］. Applied Surface Science, 2019, 494: 1100-1108.

[51] XU C B, WANG H L, YANG W J, et al. Expanded graphite modified by CTAB-KBr/H3PO4 for highly efficient adsorption of dyes［J］.Journal of Polymers and the Environment, 2018, 26(3): 1206-1217.

[52] FU W J, KIGGANS J, OVERBURY S H, et al. Low-temperature exfoliation of multilayer-graphene material from FeCl3 and CH3NO2 co-intercalated graphite compound［J］. Chemical Communications, 2011, 47(18): 5265.

[53] NAIR S S, SAHA T, DEY P, et al. Efficiency of different methods of oxidation of graphite: a key route of graphene preparation［J］.Graphene and 2D Materials Technologies, 2021, 6(1/2): 1-11.

[54] SHEN J F, HU Y Z, SHI M, et al. Fast and facile preparation of graphene oxide and reduced graphene oxide nanoplatelets［J］. Chemistry of Materials, 2009, 21(15): 3514-3520.

[55] LIANG H, LI S C, CHEN Y P, et al. Radar attenuation performance of magnetic expanded graphite aerosol obtained from thermal expansion of stage-1 ferrocene graphite intercalation compounds［J］. Materials & Design, 2020, 188: 108436.

[56] TIAN Z M, YU P, LOWE S E, et al. Facile electrochemical approach for the production of graphite oxide with tunable chemistry［J］. Carbon, 2017, 112: 185-191.

[57] WANG H, WEI C, ZHU K Y, et al. Preparation of graphene sheets by electrochemical exfoliation of graphite in confined space and their application in transparent conductive films［J］. ACS Applied Materials & Interfaces, 2017, 9(39): 34456-34466.

[58] LIU J L, POH C K, ZHAN D, et al. Improved synthesis of graphene flakes from the multiple electrochemical exfoliation of graphite rod［J］. Nano Energy, 2013, 2(3): 377-386.

[59] DAI C L, GU C L, LIU B C, et al. Preparation of low-temperature expandable graphite as a novel steam plugging agent in heavy oil reservoirs［J］. Journal of Molecular Liquids, 2019, 293: 111535.

[60] ZHAO G, DAI C L, GU C L, et al. Expandable graphite particles as a novel in-depth steam channeling control agent in heavy oil reservoirs［J］. Chemical Engineering Journal, 2019, 368: 668-677.

[61] PANG X Y, TIAN Y, WENG M Q. Preparation of expandable graphite with silicate assistant intercalation and its effect on flame retardancy of ethylene vinyl acetate composite［J］. Polymer Composites, 2015, 36(8): 1407-1416.

[62] ZHANG F S, ZHAO Q, YAN X, et al. Rapid preparation of expanded graphite by microwave irradiation for the extraction of triazine herbicides in milk samples［J］. Food Chemistry, 2016, 197: 943-949.

[63] CHUNG D D L. A review of exfoliated graphite［J］. Journal of Materials Science, 2016, 51(1): 554-568.

[64] IBARRA-HERNNDEZ A, VEGA-RIOS A, OSUNA V. Synthesis of graphite oxide with different surface oxygen contents assisted microwave radiation［J］. Nanomaterials, 2018, 8(2): 106.

[65] WU W Y, LIU M J, GU Y, et al. Fast chemical exfoliation of graphite to few-layer graphene with high quality and large size via a two-step microwave-assisted process［J］. Chemical Engineering Journal, 2020, 381: 122592.

[66] SHULGA Y M, BASKAKOV S A, KNERELMAN E I, et al. Carbon nanomaterial produced by microwave exfoliation of graphite oxide: new insights［J］. RSC Advances, 2014, 4(2): 587-592.

[67] ZHU X J, ZUO L W, WU S L, et al. Porous three-dimensional activated microwave exfoliated graphite oxide as an anode material for lithium ion batteries［J］. RSC Advances, 2016, 6(60): 55176-55181.