Page 37 - 《精细化工》2021年第4期
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第 4 期                  姚红蕊,等:  纳米氧化物颗粒增强环氧涂层防护性能的研究进展                                    ·671·


                 mesoporous-TiO 2 nanoparticles on mild steel[J]. Progress in Organic   [37]  LIU X P (刘煦平), GAO Z P (高正平). Study on the resistance to
                 Coatings, 2015, 89: 114-122.                      partial discharge corrosion of micro/nano-alumina/epoxy resin
            [20]  AN C Q (安成强), LI Q L (李庆鲁), HAO J J (郝建军). Effect of   composite[J]. Contemporary Chemical Industry (当代化工), 2019,
                 grafting density of nano-TiO 2 silane on  corrosion resistance of   48(12): 2773-2776.
                 waterborne epoxy coatings[J]. Surface Technology (表面技术), 2020,   [38]  JANAKI G B, XAVIER J R. Evaluation of mechanical properties and
                 49(3): 248-254, 339.                              corrosion protection performance of surface modified nano-alumina
            [21]  ZHANG Y L (章艳玲), MA G  Y (马国扬), LI H L  (李红玲).   encapsulated epoxy coated mild steel[J]. Journal of Bio- and Tribo-
                 Corrosion resistance of silane modified nano-titanium dioxide epoxy   Corrosion, 2019, 6(5): 1-7.
                 resin coating on aluminum alloy surface[J]. Materials Protection (材  [39]  JANAKI G B, XAVIER J R. Effect of indole functionalized
                 料保护), 2019, 52(9): 153-159.                       nano-alumina on the corrosion protection  performance of epoxy
            [22]  LIU X H, HOU P M, XIA Z, et al. The polyaniline-modified TiO 2   coatings  in marine environment[J]. Journal of Macromolecular
                 composites in water-based epoxy coating for corrosion protection of   Science, Part A, 2020, 57(10): 691-702.
                 Q235 steel[J]. Journal of Coatings Technology and Research, 2019,   [40]  YU Z X, DI H H, MA  Y,  et al. Fabrication  of graphene
                 16: 71-80.                                        oxide-alumina hybrids to reinforce the anti-corrosion performance of
            [23]  LIU J H, YU Q,  YU M,  et al. Silane modification of titanium   composite epoxy coatings[J]. Applied Surface Science, 2015,  351:
                 dioxide-decorated  graphene oxide nanocomposite for  enhancing   986-996.
                 anticorrosion performance of epoxy coatings on AA-2024[J]. Journal   [41]  CHEN L, CHEN L F L, LUO Z, et al. Study of nano-alumina impact
                 of Alloys and Compounds, 2018,774: 728-739.       on the performance of a  CaCO 3-epoxy composite coating[J].
            [24]  JIA S (贾涉), YAO Z J (姚正军), ZHANG S S (张莎莎),  et al.   Nanomaterials and Nanotechnology, 2016, 6: 115-125.
                 Anticorrosion performance of silane  modified nano TiO 2-Zn-Al/   [42]  EL-LATEEF H,  KHALAF M. Fabrication and characterization of
                 waterborne epoxy coatings[J]. Acta Materiae Compositae Sinica (复  alumina-silica/poly(o-toluidine)  nanocomposites as novel anticorrosive
                 合材料学报), 2018, 35(9): 2405-2413.                   epoxy coatings films on carbon steel[J]. Microchemical Journal,
            [25]  WANG X L, ZHOU S X, WU L M. Facile encapsulation of SiO 2 on   2020, 158: 105-129.
                 ZnO quantum dots and its application in waterborne UV-shielding   [43]  HUANG X Y, LIU H F, LIU J Q, et al. Synthesis of micro sphere
                 polymer coatings[J]. Journal of Materials Chemistry C, 2013, 1(45):   CeO 2 by a chemical precipitation method with enhanced electrochemical
                 7547-7553.                                        performance[J]. Materials Letters, 2017, 193: 115-118.
            [26]  OPREA O, ANDRONESCU E, FICAI D, et al. ZnO applications and   [44]  LI H J, MENG F M, GONG J F, et al. Structural, morphological and
                 challenges[J]. Current Organic Chemistry, 2014, 18(2): 192-203.   optical properties  of shuttle-like CeO 2 synthesized by a facile
            [27]  WONG T, LAU K, TAM W, et al. Degradation of nano-ZnO particles   hydrothermal  method[J]. Journal of Alloys and Compounds, 2017,
                 filled styrene-based and epoxy-based SMPs under UVA exposure[J].   722: 489-498.
                 Composite Structures, 2015, 132: 1056-1064.   [45]  ZHANG W B (张文博). Fabrication and study on properties of nano
            [28]  RAJ J. Application of EIS and  SECM studies for investigation  of   CeO 2/epoxy anticorrosive composite coatings[D]. Harbin:Northeast
                 anticorrosion  properties of epoxy coatings containing zinc oxide   Petroleum University (东北石油大学), 2019.
                 nanoparticles on mild steel in 3.5%  NaCl solution[J]. Journal of   [46]  ZHANG P J,  ZHU M G, LI W,  et al. Study on  preparation and
                 Materials Engineering and Performance, 2017, 26(7): 3245-3253.   properties of CeO 2/epoxy resin composite coating on sintered NdFeB
            [29]  ZHOU Q (周强), PAN M Y (潘梦雅), WANG W J (王文将), et al.   magnet[J]. Journal of Rare Earths, 2018, 36(5): 105-112.
                 Preparation and properties of composite waterborne epoxy coatings   [47]  XAVIER J R. Investigation on the effect of nano-ceria on the epoxy
                 with modified nano-ZnO[J]. Materials Protection (材料保护), 2018,   coatings for corrosion protection of mild steel in natural seawater[J].
                 51(10): 88-91.                                    Anti Corrosion Methods and Materials, 2018, 65(1): 38-45.
            [30]  HU C B, LI Y, KONG Y Z, et al. Preparation of poly(o-toluidine)/   [48]  HOSSEINI M, ABOUTALEBI K.  Improving  the anticorrosive
                 nano ZnO/epoxy composite coating and evaluation of its corrosion   performance of epoxy coatings by embedding various percentages of
                 resistance properties[J]. Synthetic Metals, 2016, 214: 62-70.   unmodified and imidazole modified CeO 2 nanoparticles[J]. Progress
            [31]  AMMAR S, RAMESH K, VENGADAESVARAN B, et al. Amelioration   in Organic Coatings, 2018, 122: 56-63.
                 of anticorrosion and hydrophobic properties of epoxy/PDMS composite   [49]  BAHLAKEH G, RAMEZANZADEH B, SAEB M, et al. Corrosion
                 coatings containing nano ZnO particles[J]. Progress in Organic   protection  properties and interfacial adhesion mechanism of an
                 Coatings, 2016,92: 54-65.                         epoxy/polyamide coating applied on the steel surface decorated with
            [32]  ROSTAMI M, RASOULI S, RAMEZANZADEH  B, et al.    cerium oxide nanofilm: Complementary experimental, molecular
                 Electrochemical investigation  of the properties of Co doped ZnO   dynamics (MD) and  first  principle quantum mechanics (QM)
                 nanoparticle as a corrosion inhibitive pigment for modifying corrosion   simulation methods[J]. Applied Surface Science, 2017, 419: 650-669.
                 resistance of the epoxy coating[J]. Corrosion Science, 2014,  88:   [50]  ZHANG W B (张文博), WANG H Y(汪怀远), WANG C J (王池嘉),
                 387-399.                                          et al. Preparation and anti-corrosion properties of modified CeO 2/
            [33]  ROUHOLLAHI A, KHALEGHI M. Epoxy-based PANI/zinc oxide/glass   NiWO 4 epoxy anticorrosive coatings[J]. Chemical Industry and
                 fiber nanocomposite coating for corrosion protection of carbon steel[J].   Engineering Progress (化工进展), 2019, 38(10): 4666-4673.
                 Materials and Corrosion, 2018, 69(3): 393-401.   [51]  RAMEZANZADEH B, BAHLAKEH G, RAMEZANZADEH M.
            [34]  KATHIRVEL P, CHANDRASEKARAN J, MANOHARAN D, et al.   Polyaniline-cerium oxide  (PANI-CeO 2) coated graphene  oxide for
                 Preparation and characterization of alpha alumina nanoparticles by   enhancement of epoxy coating corrosion protection performance on
                 in-flight oxidation of flame synthesis[J]. Journal of Alloys and   mild steel check[J]. Corrosion Science, 2018, 137: 111-126.
                 Compounds, 2014, 590: 341-345.                [52]  HABIBA S, FAYYAD  E, NAWAZ M, et  al. Cerium  dioxide
            [35]  CHEN C F, DING Z D, TAN Q, et al.Preparation of nano alpha-alumina   nanoparticles as smart carriers for self-healing coatings[J]. Nanomaterials,
                 powder and wear resistance of nanoparticles reinforced composite   2020, 10(4):791.
                 coating[J]. Powder Technology, 2014, 257: 83-87.   [53]  LIU X H, GU C J, WEN Z H, et al. Improvement of active corrosion
            [36]  CAI G H, ZHENG X H, ZHENG  Y, et al. Synthesis of ordered   protection of carbon steel by water-based epoxy coating with smart
                 mesoporous boron-doped γ-alumina with high surface area and large   CeO 2 nanocontainers[J]. Progress in Organic Coatings, 2018, 115:
                 pore volume[J]. Materials Letters, 2016, 178: 248-251.   195-204.
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