Page 20 - 《精细化工》2022年第4期
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·656·                             精细化工   FINE CHEMICALS                                 第 39 卷

                 comparison with traditional zinc phosphate coating under dry and   Physicochemical and Engineering Aspects, 2018, 555: 18-26.
                 lubricated conditions[J]. Tribology International, 2020, 144: 106122.   [29]  CHEN S S, HAN  T, ZHAO Y,  et al. A facile strategy to prepare
            [11]  LIU Y W, ZHOU X R, LYON S B,  et al. An organic coating   smart coatings with autonomous self-healing and self-reporting
                 pigmented with  strontium aluminium  polyphosphate for  corrosion   functions[J]. ACS Applied Materials & Interfaces, 2019, 12(4):
                 protection of zinc alloy coated steel[J]. Progress in Organic Coatings,   4870-4877.
                 2017, 102(Part A): 29-36.                     [30]  ATTAEI M, CALADO  L M, TARYBA M G,  et al. Autonomous
            [12]  EMAD S G R, MORSCH S, HASHIMOTO T, et al. Leaching from   self-healing in epoxy coatings provided by high efficiency
                 coatings pigmented with strontium aluminium polyphosphate   isophorone diisocyanate (IPDI) microcapsules for protection of
                 inhibitor pigment-evidence for a  cluster-percolation model[J].   carbon steel[J]. Progress in Organic Coatings, 2020, 139: 105445.
                 Progress in Organic Coatings, 2019, 137: 105340.   [31]  SUN J Y, WANG Y M, LI N, et al. Tribological and anticorrosion
            [13]  LIU D,  HAN  E H, SONG Y W,  et al. Enhancing the self-healing   behavior of self-healing coating containing nanocapsules[J].
                 property by adding the synergetic corrosion inhibitors of Na 3PO 4 and   Tribology International, 2019, 136: 332-341.
                 2-mercaptobenzothiazole into the  coating of Mg alloy[J].   [32]  KUMAR  A, STEPHENSON L  D,  MURRAY J N. Self-healing
                 Electrochimica Acta, 2019, 323: 134796.           coatings for steel[J]. Progress in Organic Coatings, 2006, 55(3):
            [14]  CHEN Y, LU X P, LAMAKA S V, et al. Active protection of Mg   244-253.
                 alloy by composite PEO coating loaded with corrosion inhibitors[J].   [33]  YU  H C, ZHANG  Y T,  WANG M  J,  et al. Dispersion of
                 Applied Surface Science, 2020, 504: 144462.       poly(urea-formaldehyde)-based microcapsules for  self-healing and
            [15]  DENG  Y J, CHEN J P, ZHANG  X M,  et al. Preparation of   anticorrosion applications[J]. Langmuir, 2019, 35(24): 7871-7878.
                 water-dispersible corrosion inhibitors for composite lacquer coatings   [34]  MA Y X, ZHANG Y R, LIU J T, et al. GO-modified double-walled
                 with excellent properties[J]. Progress in Organic Coatings, 2019,   polyurea microcapsules/epoxy composites for marine anticorrosive
                 127: 276-285.                                     self-healing coating[J]. Materials & Design, 2020, 189: 108547.
            [16]  EMAD S G R, ZHOU X R, MORSCH S, et al. How pigment volume   [35]  TEZEL Ö, ÇIGIL A B, KAHRAMAN M V.  Design and
                 concentration (PVC) and particle connectivity affect leaching of   development of self-healing coating based on thiol-epoxy
                 corrosion inhibitive species from coatings[J]. Progress in Organic   reactions[J]. Reactive and Functional Polymers, 2019, 142(9): 69-76.
                 Coatings, 2019, 134: 360-372.                 [36]  WANG J X, TANG J L,  ZHANG  H L,  et al. A  CO 2-responsive
            [17]  HARB S V, TRENTIN A, DE SOUZA T A C,  et al. Effective   anti-corrosion ethyl cellulose coating based on the pH-response
                 corrosion protection by eco-friendly self-healing PMMA-cerium   mechanism[J]. Corrosion Science, 2021, 180: 109194.
                 oxide coatings[J]. Chemical Engineering Journal, 2020, 383: 123219.   [37]  GUO Y G, WANG J, ZHANG  D W,  et al. pH-responsive
            [18]  VISSER P, TERRYN H, MOL J  M C. On the importance of   self-healing anticorrosion coatings based on benzotriazole-containing
                 irreversibility of corrosion inhibitors for active coating protection of   zeolitic imidazole framework[J]. Colloids and Surfaces A:
                 AA2024-T3[J]. Corrosion Science, 2018, 140: 272-285.   Physicochemical and Engineering Aspects, 2019, 561: 1-8.
            [19]  CHENG M, LI F T, WANG Z K, et al. New valve-free organosilica   [38]  ZHOU C L, LI Z, LI J, et al. Epoxy composite coating with excellent
                 nanocontainer for active anticorrosion  of polymer  coatings[J].   anticorrosion and self-healing performances based on multifunctional
                 Composites Part B: Engineering, 2021, 224: 109185.   zeolitic imidazolate framework derived nanocontainers[J]. Chemical
            [20]  LI C Y, GAO L, FAN X L,  et al. In vitro degradation and   Engineering Journal, 2020, 385: 123835.
                 cytocompatibility of a low temperature in-situ grown self-healing   [39]  XIONG P, JIA Z J, ZHOU W H,  et al. Osteogenic and pH
                 Mg-Al LDH  coating on MAO-coated magnesium alloy AZ31[J].   stimuli-responsive self-healing coating  on  biomedical Mg-1Ca
                 Bioactive Materials, 2020, 5(2): 364-376.         alloy[J]. Acta Biomaterialia, 2019, 92: 336-350.
            [21]  ZHAO L D, TANG B, TANG P X, et al. Chitosan/sulfobutylether-   [40]  XIONG P, YAN J  L, WANG P, et al. A pH-sensitive self-healing
                 β-cyclodextrin nanoparticles for ibrutinib  delivery:  A  potential   coating for biodegradable magnesium implants[J]. Acta Biomaterialia,
                 nanoformulation  of novel kinase inhibitor[J]. Journal  of   2019, 98: 160-173.
                 Pharmaceutical Sciences, 2019, 109(2): 1-9.   [41]  ZHAI L, NARKAR A, AHN K. Self-healing  polymers with
            [22]  CUI J, LI X Q, PEI Z Q, et al. A long-term stable and environmental   nanomaterials and nanostructures[J]. Nano Today, 2020, 30: 100826.
                 friendly self-healing coating with polyaniline/sodium alginate   [42]  SHAHIDZADEH  M, VARKANEH  Z K, RAMEZANZADEH B,
                 microcapsule structure for corrosion  protection of water-delivery   et al. Self-healing dual cured polyurethane elastomeric  coatings
                 pipelines[J]. Chemical Engineering Journal, 2019, 358: 379-388.   prepared by orthogonal reactions[J]. Progress in Organic  Coatings,
            [23]  DUAN S, DOU B J, LIN X Z, et al. Influence of active nanofiller   2020, 140: 105503.
                 ZIF-8 metal-organic framework (MOF) by microemulsion method on   [43]  URDL K, WEISS  S, CHRISTÖFL P,  et al. Diels-Alder  modified
                 anticorrosion  of epoxy coatings[J]. Colloids and  Surfaces A:   self-healing melamine resin[J]. European Polymer Journal, 2020,
                 Physicochemical and Engineering Aspects, 2021, 624: 126836.   127: 109601.
            [24]  GHORBANI M,  EBRAHIMNEZHAD-KHALJIRI H,  ESLAMI-   [44]  WANG Z Y, YANG H T, FAIRBANKS B D, et al. Fast self-healing
                 FARSANI R,  et al. The synergic  effect of microcapsules and   engineered by UV-curable polyurethane contained Diels-Alder
                 titanium nanoparticles on the self-healing and self-lubricating epoxy   structure[J]. Progress in Organic Coatings, 2019, 131: 131-136.
                 coatings: A dual smart application[J]. Surfaces and Interfaces, 2021,   [45]  AIZPURUA J, MARTIN  L, FORMOSO E,  et al. One pot
                 23: 100998.                                       stimuli-responsive linear waterborne polyurethanes  via Diels-Alder
            [25]  LI K K, LIU Z J, WANG C J, et al. Preparation of smart coatings   reaction[J]. Progress in Organic Coatings, 2019, 130: 31-43.
                 with self-healing and anti-wear properties by embedding PU-fly ash   [46]  WANG Z Y, LIANG H B, YANG  H  T,  et al. UV-curable
                 absorbing linseed oil microcapsules[J]. Progress in Organic Coatings,   self-healing polyurethane coating based on thiol-ene and Diels-Alder
                 2020, 145: 105668.                                double click reactions[J]. Progress in Organic Coatings, 2019, 137:
            [26]  CUI G, BI Z X, WANG S H, et al. A comprehensive review on smart   105282.
                 anti-corrosive coatings[J]. Progress in Organic Coatings, 2020, 148:   [47]  HONG J U, LEE  T H, OH D,  et al. Scratch-healable automotive
                 105821.                                           clearcoats based on disulfide polyacrylate urethane networks[J].
            [27]  TOOHEY K S, SOTTOS N R, WHITE S R. Characterization  of   Progress in Organic Coatings, 2021, 161: 106472.
                 microvascular-based  self-healing  coatings[J].  Experimental  [48]  ZHAO D L, LIU S S, WU Y F, et al. Self-healing UV light-curable
                 Mechanics, 2009, 49(5): 707-717.                  resins containing disulfide group: Synthesis and application in UV
            [28]  YANG S, WANG J, MAO W  Y,  et al. pH-responsive zeolitic   coatings[J]. Progress in Organic Coatings, 2019, 133: 289-298.
                 imidazole framework nanoparticles with high active inhibitor content
                 for self-healing anticorrosion coatings[J].  Colloids and Surfaces A:        (下转第 774 页)
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