نشریه شیمی و مهندسی شیمی ایران

نشریه شیمی و مهندسی شیمی ایران

مروری بر پیشرفت در فرآیندهای کپسوله‏ سازی و مکانیسم‏ های خودترمیم‏ شوندگی برای محافظت در برابر خوردگی فعال

نوع مقاله : مروری

نویسندگان
مجید میرزایی 1
طیبه محبی 2
مجید رضائی آبادچی 1
1 گروه پژوهشی مواد غیرفلزی، پژوهشگاه نیرو، تهران، ایران
2 گروه شیمی، دانشگاه کاشان، کاشان، ایران
چکیده
استفاده از پوشش‏ های آلی، رایج ترین و به صرفه ترین روش برای حفاظت در برابر خوردگی و افزایش عمر مفید بسیاری از سازه های فلزی در محیط‏ های خورنده است. با این حال، پس از ایجاد آسیب در پوشش محافظ، فرآیندهای تخریب به سرعت گسترش می‏ یابد. برای دستیابی به عملکرد طولانی مدت پوشش در محیط خورنده، حفاظت فعال به کارگرفته شده همراه  با عیوب خود ترمیم شونده ضروری است. در مقاله مروری حاضر ابتدا ویژگی مواد خودترمیم برای کاربردهای ضد خوردگی بیان شده، سپس به طبقه‏ بندی فرآیند کپسوله‏ سازی که شامل کپسوله سازی فیزیکی و شیمیایی بوده پرداخته شده و درنهایت خلاصه‌ای از کارهای اخیر در زمینه سیستم‌های حفاظتی چند سطحی جدید ارائه شده که بر اساس رهاسازی کنترل‌شده گونه‌های ضد‏خوردگی از میکرو و نانو حامل هوشمند، در یک زمینه پوشش پلیمری است. همچنین این مقاله یک رویکرد خودترمیمی که شامل چندین مکانیسم پیشگیری و ترمیم آسیب را بوده را مورد بررسی قرار می‏ دهد، که شامل به دام افتادن یون‌های خورنده، مهار خوردگی و جابجایی آب از نقص‌های فعال می باشد. در بخش دیگر مقاله مروری بر روش های ارزیابی عملکرد پوشش‏ های خود‏ترمیم‏شونده با استفاده از تکنیک های الکتروشیمیایی، سطحی و میکروسکوپی شده است و همچنین پیشنهادهایی برای تکنیک های الکتروشیمیایی جایگزین برای ارزیابی پوشش خود ترمیم شونده بررسی می شوند. در انتها در بحث مدلینگ، به تحقیقات محاسباتی در مورد مواد خود ترمیم شونده پرداخته می شود.
کلیدواژه‌ها
پوشش آلی
حفاظت فعال
مواد ضد‏خوردگی
میکرو/نانوحامل
مکانیسم ‏های خود‏ترمیم ‏شوندگی

موضوعات

[1] Nguyen T.N., Hubbard J.B., MCFADDEN G.B., A Mathematical Model for the Cathodic Blistering of Organic Coatings on Steel Immersed in Electrolytes. J. Coat. Technol. 63(794): 43-52 (1991).
[2] Mirzaee M., Rashidi A., Zolriasatein A., Rezaei Abadchi M., Corrosion Properties of Organic Polymer Coating Reinforced Two-Dimensional Nitride Nanostructures: A Comprehensive Review," J. Polym. Res. 28: 1-40 (2021).
[3] Hosseinpour A., Abadchi M.R., Mirzaee M., Tabar F.A., Ramezanzadeh B., "Recent Advances and Future Perspectives for Carbon Nanostructures Reinforced Organic Coating for Anti-CORROSION APPLICATION" Surf. Interfaces 23: 100994 (2021).
[4] وجیهه خانی.، لیلا شریفی.، آرش پیامی.، حسین کوهانی.، سیدحسین میرحسینی.، تهیه نانوپودر روی اکسید به روش سوختن ژل و استفاده از آن در ساخت پوشش های مقاوم به خوردگی کامپوزیتی پلیمر/ روی اکسید، نشریه شیمی و مهندسی شیمی ایران، 34(2): 1 تا 11 (1394).
[5] Zhou Z., Seif A., Pourhashem S., Silvestrelli P.L., Ambrosetti A., Mirzaee M., Duan J., Rashidi A., Hou B., Experimental and Theoretical Studies toward Superior Anti-corrosive Nanocomposite Coatings of Aminosilane Wrapped Layer-by-Layer Graphene Oxide@ MXene/Waterborne Epoxy. ACS Appl. Mater. Interfaces. 14(45): 51275-51290 (2022).
[6] Mirzaee M., Rashidi A., Seif A., Silvestrelli P.L., Pourhashem S., Gohari M.S., Duan J., Amino-Silane Co-Functionalized H-BN Nanofibers with Anti-Corrosive Function for Epoxy Coating. React. Funct. Polym. 174: 105244 (2022).
[7] Rezaei Abadchi M., Mirzaee M., Dorkhani E., Zolriasatein A., Noori N.R., Surface Modification of Acrylic Coating with Anti‐Corrosion and Anti‐UV Materials.  J Chin Chem Soc. 69(6): 912-924 (2022).
[8] Mirzaee M., Rezaei Abadchi M., Mehdikhani A., Riahi Noori N., Zolriasatein A., Corrosion and UV Resistant Coatings Using Fluoroethylene Vinyl Ether Polymer. Prog. Color Color. Coat. 16: 47-57 (2022).
[9] Mirzaee M., Rezaei Abadchi M., Fateh A., Zolriasatein A., Investigation of Corrosion Properties of Modified Epoxy and Polyurethane Organic Coating on Steel Substrate. Prog. Color Color. Coat. 15(1): 25-36 (2022).
[10] Shi X., Dalal N., Generation of Hydroxyl Radical by Chromate in Biologically Relevant Systems: Role of Cr (V) Complexes Versus Tetraperoxochromate (V). Environ. Health Perspect. 102(3): 231-236 (1994).
[11] Hia I.L., Vahedi V., Pasbakhsh P., Self-Healing Polymer Composites: Prospects, Challenges, and Applications. Polym. Rev.  56 (2): 225-261 (2016).
[12] Mauldin T.C., Kessler M., Self-Healing Polymers and Composites. Int. Mater. Rev. 55(6): 317-346 (2010).
[13] Bleay S., Loader C., Hawyes V., Humberstone L., Curtis P., A Smart Repair System for Polymer Matrix Composites. Compos. Part A Appl. Sci. Manuf. 32(12): 1767-1776 (2001).
[14] مهدی محمودیان.، احسان نوزاد.، تهیه و بررسی عملکرد پوشش‌های خودترمیم شونده هیبریدی متشکل از کپسول های زیرمیکرونی و بازدارنده بر روی استیل، نشریه شیمی و مهندسی شیمی ایران، 39(3): 35 الی 46 (1399).
[15] Aïssa B., Therriault D., Haddad E., Jamroz W., Self-Healing Materials Systems: Overview of Major Approaches and Recent Developed Technologies. adv. Mater. Sci. Eng. 2012 (2012).
[16] Jud K., Kausch H., Williams J., Fracture Mechanics Studies of Crack Healing and Welding of Polymers. J. Mater. Sci. 16(1): 204-210 (1981).
[17] Döhler D., Michael P., Binder W., Principles of self-Healing Polymers. W.H. Binder (Ed.) ( 2013)
[18] White S.R., Sottos N.R., Geubelle P.H., Moore J.S., Kessler M.R., Sriram S., Brown E.N., Viswanathan S., Autonomic Healing of Polymer Composites. Nature. 409(6822): 794-797 (2001).
[19] Lisenkov A., Zheludkevich M., Ferreira M., Active Protective Al–Ce Alloy Coating Electrodeposited from Ionic Liquid. Electrochem commun. 12(6): 729-732 (2010).
[20] Zheludkevich M., Tedim J., Freire C., Fernandes S.C., Kallip S., Lisenkov A., Gandini A., Ferreira., Self-healing Protective Coatings with Green Chitosan Based Pre-Layer Reservoir of Corrosion Inhibitor. J. Mater. Chem. A. 21(13): 4805-4812 (2011).
[21] Tallman D.E., Spinks G., Dominis A., Wallace G.G., Electroactive Conducting Polymers for Corrosion Control.  J. Solid State Electrochem. 6(2): 73-84 (2002).
[22] Shankar Rai R., Sepehrianazar A., Bjpai V., Developments and Prospects of Self-Healing Design for Hierarchical Carbon Fiber Reinforced Polymer Composites. Iran. J. Chem. Chem. Eng. 42(3): 890-915 (2023.)
[23] Blaiszik B.J., Baginska M., White S.R., Sottos N.R., Autonomic Recovery of Fiber/Matrix Interfacial Bond Strength in a Model Composite. Adv. Funct. Mater. 20(20): 3547-3554 (2010).
[24] Li J., Shi H., Liu F., Han E.H., Self-healing Epoxy Coating Based on Tung Oil-Containing Microcapsules for Corrosion Protection. Prog. Org. Coat. 156: 106236 (2021).
[25] Low L.E., Siva S.P., Ho Y.K., Chan E.S., Tey B.T., Recent Advances of Characterization Techniques for the Formation, Physical Properties and Stability of Pickering Emulsion. Adv. Colloid Interface Sci. 277: 102117 (2020).
[26] Bakry A.M., Abbas S., Ali B., Majeed H., Abouelwafa M.Y., Mousa A., Liang L., Microencapsulation of oils: A Comprehensive Review of Benefits, Techniques, and Applications. Compr. Rev. Food Sci. Food Saf. 15(1): 143-182 (2016).
[27] Grigoriev D.O., Haase M.F., Fandrich N., Latnikova A., Shchukin D.G., Emulsion Route in Fabrication of Micro and Nanocontainers for Biomimetic Self-Healing and Self-Protecting Functional Coatings. Bioinspired, Biomim. 1(2): 101-116 (2012).
[28] Matsuda T., Jadhav N., Kashi K.B., Jensen M., Suryawanshi A., Gelling V.J., Self-Healing Ability and Particle Size Effect of Encapsulated Cerium Nitrate into pH Sensitive Microcapsules. Prog. Org. Coat. 90: 425-430 (2016).
[29] Schreiner C., Scharf S., Stenzel V., Rössler A., Self-healing Through Microencapsulated Agents for Protective Coatings. J. Coat. Technol. Res. 14: 809-816 (2017).
[30] Jialan Y., Chenpeng Y., Chengfei Z., Baoqing H., Preparation Process of Epoxy Resin Microcapsules for Self-Healing Coatings. Prog. Org. Coat. 132: 440-444 (2019).
[31] Kakran M., Antipina M.N., Emulsion-Based Techniques for Encapsulation in Biomedicine, Food and Personal Care. Curr Opin Pharmacol. 18: 47-55 (2014).
[32] Kim C., Karayan A.I., Milla J., Hassan M., Castaneda H., Smart Coating Embedded with pH-Responsive Nanocapsules Containing A Corrosion Inhibiting Agent. ACS Appl. Mater. Interfaces. 12(5): 6451-6459 (2020).
[33] Vauthier C., Dubernet C., Chauvierre C., Brigger I., Couvreur P., Drug Delivery to Resistant Tumors: the Potential of Poly (Alkyl Cyanoacrylate) Nanoparticles. J Control Release. 93(2): 151-160, (2003).
[34] Alizadegan F., Mirabedini S.M., Pazokifard S., Moghadam S.G., Farnood R., Improving Self-Healing Performance of Polyurethane Coatings Using PU Microcapsules Containing Bulky-IPDI-BA and Nano-Clay. Prog. Org. Coat. 123: 350-361 (2018).
 [35] Li J., Feng Q., Cui J., Yuan Q., Qiu H., Gao S., Yang J., Self-Assembled Graphene Oxide Microcapsules in Pickering Emulsions for Self-Healing Waterborne Polyurethane Coatings,. Compos Sci Technol. 151: 282-290 (2017).
[36] Zacchi P., Pietsch A., Voges S., Ambrogi A., Eggers R., Jaeger  P., Concepts of Phase Separation in Supercritical Processing. Chem Eng Process. 5(9): 728-733 (2006).
[37] Ouarga A., Lebaz N., Tarhini M., Noukrati H., Barroug A., Elaissari A., Towards Smart Self-Healing Coatings: Advances in Micro/Nano-Encapsulation Processes as Carriers for Anti-Corrosion Coatings Development. J. Mol. Liq. 118862 (2022).
[38] Haug I., Williams M.A., Lundin L., Smidsrød O., Draget K.I., Molecular Interactions in, and Rheological Properties of, a Mixed Biopolymer System Undergoing Order/Disorder Transitions. Food Hydrocoll. 17(4): 439-444 (2003).
[39] Song J., Cui X., Liu Z., Jin G., Liu E., Zhang D., Gao Z., Advanced Microcapsules for Self-Healing Conversion Coating on Magnesium Alloy in Ce (NO3) 3 Solution with Microcapsules Containing La (NO3) 3. Surf. Coat. Technol. 307: 500-505 (2016).
[40] Arpagaus C., Collenberg A., Rütt D., Assadpour E., Jafari S.M., Nano Spray Drying for Encapsulation of Pharmaceuticals. Int. J. Pharm. 546(1-2): 194-214 (2018).
[41] Ahangaran F., Hayaty M., Navarchian A.H., Morphological Study of Polymethyl Methacrylate Microcapsules Filled With Self-Healing Agents.  Appl. Surf. Sci. 399: 721-731(2017).
[42] Abbaspoor S., Ashrafi A., Abolfarsi R., Development of Self-Healing Coatings Based on Ethyl Cellulose Micro/Nano-Capsules. Surf. Eng. 35(3): 273-280 (2019).
[43] Cotting F., Aoki I.V., Smart Protection Provided by Epoxy Clear Coating Doped with Polystyrene Microcapsules Containing Silanol and Ce (III) Ions as Corrosion Inhibitors. Surf. Coat. Technol. 303: 310-318 (2016).
[44] Richard J., Benoit J., Microencapsulation. Tech. L’ingénieur . J2, 210: 1-20 (2000).
[45] Zheludkevich M.L., Shchukin D.G., Yasakau K.A., Möhwald H., Ferreira M.G., Anticorrosion Coatings with Self-Healing Effect Based on Nanocontainers Impregnated with Corrosion Inhibitor. Chem. Mater. 19(3): 402-411 (2007).
[46] Neuser S., Chen P.W., Studart A.R., Michaud V., Fracture Toughness Healing in Epoxy Containing Both Epoxy and Amine Loaded Capsules. Adv Eng Mater. 16(5): 581-587 (2014).
[47] Chen P.W., Cadisch G., Studart A.R., Encapsulation of Aliphatic Amines using Microfluidics. Langmuir. 30(9): 2346-2350 (2014).
[48] Soottitantawat A., Takayama K., Okamura K., Muranaka D., Yoshii H., Furuta T., Ohkawara M., Linko P., Microencapsulation of l-Menthol by Spray Drying and its Release Characteristics, Innov. Food Sci. Emerg. Technol. 6(2): 163-170 (2005).
[49] Shirokawa K., Taguchi Y., Yokoyama H., Ono F., Tanaka M., Preparation of Temperature and Water Responsive Microcapsules Containing Hydroquinone with Spray Drying Method. J. cosmet. dermatol. sci. appl. 3(3): 49 (2013).
[50] Poncelet D., Microencapsulation: Fundamentals, Methods and Applications, in Surface Chemistry in Biomedical and Environmental Science: Springer: 23-34 (2006).
[51] Liu T., Ma L., Wang X., Wang J., Qian H., Zhang D., Li X., Self-Healing Corrosion Protective Coatings Based on Micro/Nanocarriers: A Review. Corros. Commun. 1: 18-25 (2021).
[52] Niu M., Wang X., Yang Y., Hou W., Dai J., LiuX., Xu B., The Structure of Microencapsulated Carbon Microspheres and its Flame Retardancy in Poly (Ethylene Terephthalate).  Prog. Org. Coat. 95: 79-84 (2016).
[53] Wang L., Advani S.G., Prasad A.K., Self-Healing Composite Membrane for Proton Electrolyte membrane fuel cell applications. J. Electrochem. Soc. 163(10): 1267(2016).
[54] Koh E., Park S., Self-Anticorrosion Performance Efficiency of Renewable Dimer-Acid-Based Polyol Microcapsules Containing Corrosion Inhibitors with Two Triazole Groups.  Prog. Org. Coat. 109: 61-69 (2017).
[55] Tatiya P.D., Mahulikar P.P., Gite V.V., Designing of Polyamidoamine-Based Polyurea Microcapsules Containing Tung Oil for Anticorrosive Coating Applications. J. Coat. Technol. Res. 13: 715-726 (2016).
[56] Ouarga A., Noukrati H., Iraola-Arregui I., Elaissari A., Barroug A., Development of Anti-Corrosion Coating Based on Phosphorylated Ethyl Cellulose Microcapsules. Prog. Org. Coat. 148: 105885 (2020).
[57] Eftekhari A., Nanostructured conductive polymers. John Wiley & Sons (2011)
[58] Lamaka S., Montemor M., Galio A., Zheludkevich M., Trindade C., Dick L., Ferreira M., Novel Hybrid Sol–Gel Coatings for Corrosion Protection of AZ31B Magnesium Alloy. Electrochim. Acta. 53(14): 4773-4783 (2008).
[59] Zheludkevich M., Serra R., Montemor M., Yasakau K., Salvado I.M., Ferreira M., Nanostructured Sol–Gel Coatings Doped with Cerium Nitrate as Pre-Treatments for AA2024-T3: Corrosion protection performance. Electrochim. Acta. 51(2): 208-217 (2005).
[60] Zheludkevich M.L., Serra R., Montemor M.F., Ferreira M.G., Oxide Nanoparticle Reservoirs for Storage and Prolonged Release of the Corrosion Inhibitors. Electrochem commun. 7(8): 836-840 (2005).
[61] Peñas-Caballero M., Martín-Cordón J., Barranco V., Galván J.C., Santana M.H., Lopez-Manchado M.A., Verdejo R., Corrosion Control by Autonomous Self-Healing Epoxy Coatings Based on Superabsorbent Healing Agents. Prog. Org. Coat. 182: 107600 (2023).
[62] Budiarto W., Riastuti R., Darsono N., Thaha Y.N., EIS Analysis of Corrosion Behavior of Aluminum dross Concrete in Chloride Environment. AIP Conf. Proc. 2538(1): (2023).
[63] Wang Q., Wang R., Zhang Q., Zhao C., Zhou X., Zheng H., Zhang R., Sun Y., Yan Z., Application of Biomass Corrosion Inhibitors in Metal Corrosion Control: A Review. Molecules. 28(6): 2832 (2023).
[64] Castela A., Simoes A., An Impedance Model for the Estimation of Water Absorption in Organic Coatings. Part I: A Linear Dielectric Mixture Equation. Corros Sci. 45(8): 1631-1646 (2003).
[65] Zheludkevich M., Serra R., Montemor M., Salvado I.M., Ferreira M., Corrosion Protective Properties of Nanostructured Sol–Gel Hybrid Coatings to AA2024-T3. Surf. Coat. Technol. 200(9): 3084-3094 (2006).
[66] Shchukin D.G., Zheludkevich M., Yasakau K., Lamaka S., Ferreira M.G., Möhwald., Layer‐by‐Layer Assembled Nanocontainers for Self‐Healing Corrosion Protection. Adv. Mater. 18(13): 1672-1678 (2006).
[67] Shchukin D.G., Lamaka S., Yasakau K., Zheludkevich M., Ferreira M., Möhwald H., Active Anticorrosion Coatings with Halloysite Nanocontainers. J. Phys. Chem. C. 112(4): 958-964 (2008).
[68] McMurray H., Williams D., Williams G., Worsley D., Inhibitor Pretreatment Synergies Demonstrated Using a Scanning Kelvin Probe Technique. Corros. Eng. Sci. Technol. 38(2): 112-118 (2003).
[69] Bohm S., McMurray H., Worsley D., Powell S., Novel Environment Friendly Corrosion Inhibitor Pigments Based on Naturally Occurring Clay Minerals. Mater. Corros. 52(12): 896-903 (2001).
[70] Buchheit R.G., Guan H., Mahajanam S., Wong F., Active Corrosion Protection and Corrosion Sensing in Chromate-Free Organic Coatings. Prog. Org. Coat.  47(3-4): 174-182 (2003).
[71] Poznyak S., Tedim J., Rodrigues L., Salak A., Zheludkevich M., Dick L., Ferreira M., Novel Inorganic Host Layered Double Hydroxides Intercalated with Guest Organic Inhibitors for Anticorrosion Applications. ACS Appl. Mater. Interfaces. 1(10): 2353-2362 (2009).
[72] Tedim J., Poznyak S., Kuznetsova A., Raps D., Hack T., Zheludkevich M., Ferreira M., Enhancement of Active Corrosion Protection Via Combination of Inhibitor-Loaded Nanocontainers, ACS Appl. Mater. Interfaces. 2(5): 1528-1535 (2010).
[73] Zheludkevich M., Poznyak S., Rodrigues L., Raps D., Hack T., Dick L., Nunes T., Ferreira M., Active Protection Coatings with Layered Double Hydroxide Nanocontainers of Corrosion Inhibitor. Corros Sci. 52(2): 602-611 (2010).
[74] Williams G., McMurray H.N., Inhibition of Filiform Corrosion on Polymer Coated AA2024-T3 by Hydrotalcite-Like Pigments Incorporating Organic Anions. Electrochem. solid-state lett. 7(5): B13 (2004).
[75] Kendig M., Hon M., A Hydrotalcite-Like Pigment Containing an Organic Anion Corrosion Inhibitor.  Electrochem. solid-state lett. 8(3): B10 (2005).
[76] Kumar A., Stephenson L., Murray J.N., Self-healing Coatings for Steel. Prog. Org. Coat. 55(3): 244-253 (2006).
[77] Zhang F., Ju P., Pan M., Zhang D., Huang Y., Li G., Li X., Self-Healing Mechanisms in Smart Protective Coatings: A Review. Corros Sci. 144: 74-88 (2018).
[78] Ghoshal J., Inhibition of Microbial Corrosion by Green Inhibitors: An Overview. Iran. J. Chem. Chem. Eng. 42(2): 684-703 (2022).
[79] Aramaki K., Shimizu K., Sakakibara M., Nishihara H., Corrosion of Iron in Anhydrous Acetonitrile Solutions of Some Carboxylic Acids. J. Electrochem. Soc. 140(6): 1561 (1993).
[80] Robles D., Brizuela A., Fernández-Domínguez M., Gil J., Corrosion Resistance and Titanium Ion Release of Hybrid Dental Implants. Materials, 16(10): 3650 (2023).
[81] Kowalski D., Ueda M., Ohtsuka T., Self-healing Ion-Permselective Conducting Polymer Coating. J. Mater. Chem, 20(36): 7630-7633 (2010).
[82] Yabuki A., Okumura K., Self-Healing Coatings Using Superabsorbent Polymers for Corrosion Inhibition in Carbon Steel. Corros Sci. 59: 258-262 (2012).
[83] Gnedenkov A.S., Sinebryukhov S.L., Filonina V.S., Ustinov A.Y., Sukhoverkhov S.V., Gnedenkov S.V., New Polycaprolactone-Containing Self-Healing Coating Design for Enhance Corrosion Resistance of the Magnesium and Its Alloys. Polymers. 15(1): 202 (2022).
[84] Cheng M., Fu Q., Tan B., Ma Y., Fang L., Lu C., Xu Z., Build a Bridge from Polymeric Structure Design to Engineering Application of Self-Healing Coatings: A Review. Prog. Org. Coat. 167: 106790 (2022).
[85] García S., Fischer H., White P., Mardel J., González-García Y., Mol J., Hughes., Self-Healing Anticorrosive Organic Coating Based on an Encapsulated Water Reactive Silyl Ester: Synthesis and Proof of Concept. Prog. Org. Coat. 70(2-3): 142-149 (2011).
[86] Goyal R., Yadav M., Study on Wear and Friction Behavior of Graphite Flake‐Filled PTFE Composites, J. Appl. Polym. Sci. 127(4): 3186-3191 (2013).
[87] Jadhav R.S., Hundiwale D.G., Mahulikar., Synthesis and Characterization of Phenol–Formaldehyde Microcapsules Containinglinseed Oil and Its Use in Epoxy for Self-Healing and Anticorrosive Coating. J. Appl. Polym. Sci. 119(5): 2911-2916 (2011).
[88] Li R., Tian S., Tian Y., Wang J., Xu S., Yang K., Yang J., Zhang L., An Extreme-Environment-Resistant Self-Healing Anti-Icing Coating. Small. 19(10): 2206075 (2023).
[89] Ahmad S., Habib S., Nawaz M., Shakoor R.A., Kahraman R., Mohammed Al Tahtamouni T., The Role of Polymeric Matrices on the Performance of Smart Self-Healing Coatings: A Review. J Ind Eng Chem 124: 40-67 (2023).
[90] Huang M., Yang J., Facile Microencapsulation of HDI for Self-Healing Anticorrosion Coatings. J. Mater. Chem.  21(30): 11123-11130 (2011).
[91] Yabuki A., Urushihara W., Kinugasa J., Sugano K., Self‐healing Properties of TiO2 Particle–Polymer Composite Coatings for Protection of Aluminum Alloys Against Corrosion in Seawater. Corros. Mater., 62(10): 907-912 (2011).
[92] Wu W., Chu L., Garcia S.J., van der Zwaag S., Li M., Shen L., Bao N., Fabrication of Graphene Oxide-Modified Self-Healing Microcapsules for Cardanol-Based Epoxy Anti-Corrosion Coatings. Prog. Org. Coat. 183(7): 10777 (2023).
[93] Aramaki K., Self-Healing Mechanism of an Organosiloxane Polymer Film Containing Sodium Silicate and Cerium(III) Nitrate for Corrosion of Scratched Zinc Surface in 0.5 M NaCl. Corr Sci. 44(7): 1621-1632 (2002).
[94] Siva T., Kandhasamy K., Vaduganathan K., Sathiyanarayanan S., Ramadoss A., Electrosynthesis of Silica Reservoir Incorporated Dual Stimuli Responsive Conducting Polymer-Based Self-Healing Coatings. Ind. Eng. Chem. Res. 62(9): 3942-3951 (2023).
[95] Nóvoa X.R., Pérez C., The use of Smart Coatings for Metal Corrosion Control. Curr. Opin. Electrochem. 40: 101324 (2023).
[96] Peñas-Caballero M., Martín-Cordón J., Barranco V., GalvánJ.C., Hernández Santana M., Lopez-Manchado M.A., Verdejo R., Corrosion Control by Autonomous Self-Healing Epoxy Coatings Based on Superabsorbent Healing Agents. Prog. Org. Coat. 182: 107600 (2023).
[97] Zhao Y., Li Y., Kuermanbayi S., Liu Y., Zhang J., Ye Z., Guo H., Qu K., Xu F., Li F., In Situ and Quantitatively Monitoring the Dynamic Process of Ferroptosis in Single Cancer Cells by Scanning Electrochemical Microscopy. Anal. Chem. 95(3): 1940-1948 (2023).
[98] Huang Y., Zhao Z., Liu H., Zou X., Wang J.,  Two Combination Strategies of Coordinated Silicon Elastomer and Modified Nano-Silica to Fabricate Self-Healing Hybrid coating@fabrics with High Oil-Water Separation Capabilities. Colloids Surf. A: Physicochem. Eng. Asp. 658: 130685(2023).
[99] Cappellesso V., di Summa D. Pourhaji P., Prabhu Kannikachalam N., Dabral K., Ferrara L., Cruz Alonso M., Camacho E., Gruyaert E., De Belie N., A Review of the Efficiency of Self-Healing Concrete Technologies for Durable and Sustainable Concrete Under Realistic Conditions.  Int. Mater. Rev. 68(5): 556-603 (2023). 
[100] Perry S.C., Arumugam S., Beeby S., Nandhakumar I., Template-Free Nanostructured Poly-3-Hexylthiophene (P3HT) Films Via Single Pulse-Nucleated Electrodeposition.  J. Electroanal. Chem. 933: 117278 (2023).
[101] Huang Y., Zhao C., Li Y., Wang C., Shen T., Cheng, D., Yang H., Development of Self-Healing Sol-Gel Anticorrosion Coating with pH-Responsive 1H-Benzotriazole-Inbuilt Zeolitic Imidazolate Framework Decorated with Silica Shell. Surf. Coat. 466: 129622 (2023).
[102] Brancart J., Verhelle R., Mangialetto J., Van Assche G., Coupling the Microscopic Healing Behaviour of Coatings to the Thermoreversible Diels-Alder Network Formation. Coatings. 9(1): 13(2019).
[103] Zhang M., Yang Q., Hu T., Tang L., Ni Y., Chen L., Wu H., Huang L., Ding C., Adhesive, Antibacterial, Conductive, Anti-UV, Self-Healing, and Tough Collagen-Based Hydrogels from a Pyrogallol-Ag Self-Catalysis System. ACS Appl. Mater. Interfaces. 14(7): 8728-874 (2022).
[104] Sáiz L.M., Prolongo M.G., Bonache V., Jiménez-Suárez A., Prolongo S.G., Self-Healing Materials Based on Disulfide Bond-Containing Acrylate Networks. Polym Test. 117: 107832 (2023).
[105] Javierre E., Modeling Self-Healing Mechanisms in Coatings: Approaches and Perspectives. Coatings. 9(2): 122 (2019).
[106] Sottos N., White S., Bond I., Introduction: Self-Healing Polymers and Composites. J. R. Soc. Interface. 4(13): 347-348 (2007).
[107] Waters J.T., Liu Y., Li L., Balazs A.C., Optimizing Micromixer Surfaces To Deter Biofouling. ACS Appl. Mater. Interfaces. 10(9): 8374-8383 (2018).
[108] Lee J.Y., Buxton G.A., Balazs A.C., Using Nanoparticles to Create Self-Healing Composites. J. Chem. Phys. 121(11): 5531-5540 (2004).
[109] Greeley J., Jaramillo T.F., Bonde J., Chorkendorff I., Nørskov J.K., Computational High-Throughput Screening of Electrocatalytic Materials for Hydrogen Evolution.  Nat. Mater. 5(11): 909-913 (2006).
[110] Tyagi S., Lee J.Y., Buxton G.A., Balazs A.C., Using Nanocomposite Coatings to Heal Surface Defects," Macromolecules, 37(24): 9160-9168 (2004).
[111] Smith K.A., Tyagi S., Balazs A.C., Healing Surface Defects with Nanoparticle-Filled Polymer Coatings: Effect of Particle Geometry. Macromolecules. 38(24): 10138-10147(2005).
[112] Costagliola G., Bosia F., Pugno N.M., Random Fuse Model in the Presence of Self-Healing. New J. Phys. 22(3): 033005 (2020).
[113] Buxton G.A., Care C.M., Cleaver D.J., A Lattice Spring Model of Heterogeneous Materials with Plasticity. Model Simul Mat Sci Eng, 9(6): 485 (2001).