Research Progress in Application of Graphene Oxide Based Nanohybrid in Anti-corrosive Coatings

MU Songwei; LIANG Yu; ZHANG Xinyue; CHEN Kaifeng; WANG Jingjing

Volume 36 Issue 6

Dec. 2021

Turn off MathJax

Article Contents

Article Navigation > Development and Application of Materials > 2021 > 36(6): 83-90,102

MU Songwei, LIANG Yu, ZHANG Xinyue, CHEN Kaifeng, WANG Jingjing. Research Progress in Application of Graphene Oxide Based Nanohybrid in Anti-corrosive Coatings[J]. Development and Application of Materials, 2021, 36(6): 83-90,102.

Citation:

MU Songwei, LIANG Yu, ZHANG Xinyue, CHEN Kaifeng, WANG Jingjing. Research Progress in Application of Graphene Oxide Based Nanohybrid in Anti-corrosive Coatings[J]. Development and Application of Materials, 2021, 36(6): 83-90,102.

Citation:

PDF( 5695 KB)

Research Progress in Application of Graphene Oxide Based Nanohybrid in Anti-corrosive Coatings

1. Xiamen Branch of Luoyang Ship Material Research Institute, Xiamen 361101, China;
2. Science and Technology on Marine Corrosion and Protection Laboratory, Luoyang Ship Material Research Institute, Qingdao 266101, China

Received Date: 2021-06-03
Publish Date: 2021-12-25

Abstract

Abstract

Graphene oxide (GO) has the features of high specific surface area and good barrier, which can be used as filler to enhance the corrosion resistance of coatings. However, the interaction between the graphene oxide sheets makes it easy to form aggregates, which hinders the full play of its barrier properties. Serious aggregation may even lead to poor mechanical properties of the coating. In addition to GO, other nanomaterials are also widely used in anticorrosive coatings and show complementary functions with GO. The results show that the nanohybrid compounds obtained by surface modification of GO and other nanomaterials could help anticorrosive coatings achieve better anticorrosive performances. Based on the study, the research progress of GO based nano-hybrid system in improving anticorrosion performance of coatings is summarized, and its future development trend prospected.
- graphene oxide,
- anti-corrosive,
- synergistic effect,
- nanohybrid

FullText(HTML)

References(58)

References

[1]	YU J H, HUO R M, WU C, et al. Influence of interface structure on dielectric properties of epoxy/alumina nanocomposites[J]. Macromolecular Research, 2012, 20(8):816-826.
[2]	BAGHERZADEH M R, MAHDAVI F, GHASEMI M, et al. Using nanoemeraldine salt-polyaniline for preparation of a new anticorrosive water-based epoxy coating[J]. Progress in Organic Coatings, 2010, 68(4):319-322.
[3]	HE Y, XU W, TANG R, et al. pH-Responsive nanovalves based on encapsulated halloysite for the controlled release of a corrosion inhibitor in epoxy coating[J]. RSC Advances, 2015, 5(110):90609-90620.
[4]	赵一志, 沈志刚, 张晓静, 等. 二维纳米材料在腐蚀防护中的应用研究进展[J]. 中国粉体技术, 2021, 27(1):11-21.
[5]	HAGHDADEH P, GHAFFARI M, RAMEZANZADEH B, et al. The role of functionalized graphene oxide on the mechanical and anti-corrosion properties of polyurethane coating[J]. Journal of the Taiwan Institute of Chemical Engineers, 2018, 86:199-212.
[6]	王池嘉, 王子华, 刘书佩, 等. 新型碳纳米材料用于有机防腐涂层的研究进展[J]. 表面技术, 2021, 50(3):1-15.
[7]	JIA Z W, SUN W C, GUO F, et al. Microstructure, friction and corrosion resistance properties of a Ni-Co-Al₂O₃ composite coating[J]. RSC Advances, 2018, 8(22):12138-12145.
[8]	RAMEZANZADEH B, HAERI Z, RAMEZANZADEH M. A facile route of making silica nanoparticles-covered graphene oxide nanohybrids (SiO₂-GO); fabrication of SiO₂-GO/epoxy composite coating with superior barrier and corrosion protection performance[J]. Chemical Engineering Journal, 2016, 303:511-528.
[9]	SONG B J, SHI Y C, LIU Q D. An inorganic route to decorate graphene oxide with nanosilica and investigate its effect on anti-corrosion property of waterborne epoxy[J]. Polymers for Advanced Technologies, 2020, 31(2):309-318.
[10]	POURHASHEM S, VAEZI M R, RASHIDI A, et al. Distinctive roles of silane coupling agents on the corrosion inhibition performance of graphene oxide in epoxy coatings[J]. Progress in Organic Coatings, 2017, 111:47-56.
[11]	LIU L Q, GUO X F, SHI L, et al. SiO₂-GO nanofillers enhance the corrosion resistance of waterborne polyurethane acrylic coatings[J]. Advanced Composites Letters, 2020, 29:2633366X2094152.
[12]	DU P, WANG J, ZHAO H C, et al. Graphene oxide encapsulated by mesoporous silica for intelligent anticorrosive coating:studies on release models and self-healing ability[J]. Dalton Transactions, 2019, 48(34):13064-13073.
[13]	XU J B, CAO Y Q, FANG L, et al. A one-step preparation of inhibitor-loaded silica nanocontainers for self-healing coatings[J]. Corrosion Science, 2018, 140:349-362.
[14]	SOGUKKANLI S, YILMAZOGLU M, TASDELEN M A, et al. Hybrid film properties of the linseed oil based alkyd resin modified with glycidyl polyhedral oligomeric silsesquioxane[J]. Progress in Organic Coatings, 2018, 124:175-184.
[15]	梁宇, 陈凯锋, 亓海霞, 等. pH敏感释放型缓蚀防锈填料的制备及性能研究[J]. 材料开发与应用, 2018, 33(1):94-99.
[16]	WANG Y, WEI D B, YU J, et al. Effects of Al₂O₃ nano-additive on performance of micro-arc oxidation coatings formed on AZ91D Mg alloy[J]. Journal of Materials Science & Technology, 2014, 30(10):984-990.
[17]	BALANI K, AGARWAL A. Process map for plasma sprayed aluminum oxide-carbon nanotube nanocomposite coatings[J]. Surface and Coatings Technology, 2008, 202(17):4270-4277.
[18]	TATSUMA T, SAITOH S, OHKO Y, et al. TiO₂-WO₃ photoelectrochemical anticorrosion system with an energy storage ability[J]. Chemistry of Materials, 2001, 13(9):2838-2842.
[19]	YU Z X, DI H H, MA Y, et al. Preparation of graphene oxide modified by titanium dioxide to enhance the anti-corrosion performance of epoxy coatings[J]. Surface and Coatings Technology, 2015, 276:471-478.
[20]	XIA Y Z, CHENG H, DUO L J, et al. Anticorrosion reinforcement of waterborne polyacrylate coating with nano-TiO₂ loaded graphene[J]. Journal of Applied Polymer Science, 2020, 137(21):48733.
[21]	LAI G H, HUANG T C, TSENG I H, et al. Transparency anticorrosion coatings prepared from alumina-covered graphene oxide/polyimide nanocomposites[J]. Express Polymer Letters, 2019, 13(9):772-784.
[22]	WANG C Y, QIN Z H, FENG K, et al. CeO₂ modified graphene nanoplatelets composite powders enhanced the cathodic protection of waterborne zinc-rich epoxy coatings[J]. Journal of Polymer Research, 2020, 27(12):1-10.
[23]	RAMEZANZADEH B, BAHLAKEH G, RAMEZANZADEH M. Polyaniline-cerium oxide (PAni-CeO₂) coated graphene oxide for enhancement of epoxy coating corrosion protection performance on mild steel[J]. Corrosion Science, 2018, 137:111-126.
[24]	CHHETRI S, GHOSH S, SAMANTA P, et al. Effect of Fe₃O₄-decorated N-doped reduced graphene oxide nanohybrid on the anticorrosion performance of epoxy composite coating[J]. Chemistry Select, 2019, 4(46):13446-13454.
[25]	CAO K Y, YU Z X, YIN D. Preparation of Ce-MOF@TEOS to enhance the anti-corrosion properties of epoxy coatings[J]. Progress in Organic Coatings, 2019, 135:613-621.
[26]	YIN D. Enhancement of the anti-corrosion performance of composite epoxy coatings in presence of BTA-loaded copper-based metal-organic frameworks[J]. International Journal of Electrochemical Science, 2019:4240-4253.
[27]	KUO S W, CHANG F C. POSS related polymer nanocomposites[J]. Progress in Polymer Science, 2011, 36(12):1649-1696.
[28]	HOU K, ZENG Y C, ZHOU C L, et al. Facile generation of robust POSS-based superhydrophobic fabrics via thiol-ene click chemistry[J]. Chemical Engineering Journal, 2018, 332:150-159.
[29]	CHEN S Y, GUO L H, DU D X, et al. Waterborne POSS-silane-urethane hybrid polymer and the fluorinated films[J]. Polymer, 2016, 103:27-35.
[30]	YE Y W, YANG D P, ZHANG D W, et al. POSS-tetraaniline modified graphene for active corrosion protection of epoxy-based organic coating[J]. Chemical Engineering Journal, 2020, 383:123160.
[31]	GOU L, MA L, ZHAO M J, et al. Co-based metal-organic framework and its derivatives as high-performance anode materials for lithium-ion batteries[J]. Journal of Materials Science, 2019, 54(2):1529-1538.
[32]	CHANG H, WANG Y, XIANG L, et al. Improved H₂/CO₂ separation performance on mixed-linker ZIF-7 polycrystalline membranes[J]. Chemical Engineering Science, 2018, 192:85-93.
[33]	LEITE J P, GALES L. Fluorescence properties of the amyloid indicator dye thioflavin T in constrained environments[J]. Dyes and Pigments, 2019, 160:64-70.
[34]	GUPTA V, TYAGI S, PAUL A K. Development of biocompatible iron-carboxylate metal organic frameworks for pH-responsive drug delivery application[J]. Journal of Nanoscience and Nanotechnology, 2019, 19(2):646-654.
[35]	LIU C, MULLINS M, HAWKINS S, et al. Epoxy nanocomposites containing zeolitic imidazolate framework-8[J]. ACS Applied Materials & Interfaces, 2018, 10(1):1250-1257.
[36]	LEE S H, SEO H Y, YEOM Y S, et al. Rational design of epoxy/ZIF-8 nanocomposites for enhanced suppression of copper ion migration[J]. Polymer, 2019, 167:224-225.
[37]	RAMEZANZADEH M, RAMEZANZADEH B, MAHDAVIAN M, et al. Development of metal-organic framework (MOF) decorated graphene oxide nanoplatforms for anti-corrosion epoxy coatings[J]. Carbon, 2020, 161:231-251.
[38]	CAO K Y, YU Z X, YIN D, et al. Fabrication of BTA-MOF-TEOS-GO nanocomposite to endow coating systems with active inhibition and durable anticorrosion performances[J]. Progress in Organic Coatings, 2020, 143:105629.
[39]	LIU C, ZHAO H, HOU P, et al. Efficient graphene/cyclodextrin-based nanocontainer:synthesis and host-guest inclusion for self-healing anticorrosion application[J]. ACS Applied Materials & Interfaces, 2018, 10(42):36229-36239.
[40]	LV C, WANG H Y, LIU Z J, et al. Fabrication of durable fluorine-free polyphenylene sulfide/silicone resin composite superhydrophobic coating enhanced by carbon nanotubes/graphene fillers[J]. Progress in Organic Coatings, 2019, 134:1-10.
[41]	WANG L L, ZHU G H, YU W, et al. Integrating nitrogen-doped graphitic carbon with Au nanoparticles for excellent solar energy absorption properties[J]. Solar Energy Materials and Solar Cells, 2018, 184:1-8.
[42]	GAO X Z, LIU H J, CHENG F, et al. Thermoresponsive polyaniline nanoparticles:Preparation, characterization, and their potential application in waterborne anticorrosion coatings[J]. Chemical Engineering Journal, 2016, 283:682-691.
[43]	SUN M, YEROKHIN A, BYCHKOVA M Y, et al. Self-healing plasma electrolytic oxidation coatings doped with benzotriazole loaded halloysite nanotubes on AM50 magnesium alloy[J]. Corrosion Science, 2016, 111:753-769.
[44]	ZAHIDAH K A, KAKOOEI S, ISMAIL M C, et al. Halloysite nanotubes as nanocontainer for smart coating application:a review[J]. Progress in Organic Coatings, 2017, 111:175-185.
[45]	CHEN L G, YU Z X, YIN D, et al. Preparation and anticorrosion properties of BTA@HNTs-GO nanocomposite smart coatings[J]. Composite Interfaces, 2021, 28(1):1-16.
[46]	JIA Y L, QIU T, GUO L H, et al. Preparation of pH responsive smart nanocontainer via inclusion of inhibitor in graphene/halloysite nanotubes and its application in intelligent anticorrosion protection[J]. Applied Surface Science, 2020, 504:144496.
[47]	JIA Y L, QIU T, GUO L H, et al. Reduction-coagulation preparation of hybrid nanoparticles of graphene and halloysite nanotubes for use in anticorrosive waterborne polymer coatings[J]. ACS Applied Nano Materials, 2018, 1(4):1541-1550.
[48]	HUSAIN E, NARAYANAN T N, TAHA-TIJERINA J J, et al. Marine corrosion protective coatings of hexagonal boron nitride thin films on stainless steel[J]. ACS Applied Materials & Interfaces, 2013, 5(10):4129-4135.
[49]	KHAN M H, JAMALI S S, LYALIN A, et al. Atomically thin hexagonal boron nitride nanofilm for Cu protection:the importance of film perfection[J]. Advanced Materials, 2017, 29(4):1603937.
[50]	SHEN L T, ZHAO Y D, WANG Y, et al. A long-term corrosion barrier with an insulating boron nitride monolayer[J]. Journal of Materials Chemistry A, 2016, 4(14):5044-5050.
[51]	WU Y Q, HE Y, CHEN C L, et al. Non-covalently functionalized boron nitride by graphene oxide for anticorrosive reinforcement of water-borne epoxy coating[J]. Colloids and Surfaces A:Physicochemical and Engineering Aspects, 2020, 587:124337.
[52]	HUANG H W, HUANG X F, XIE Y H, et al. Fabrication of h-BN-rGO@PDA nanohybrids for composite coatings with enhanced anticorrosion performance[J]. Progress in Organic Coatings, 2019, 130:124-131.
[53]	TEDIM J, KUZNETSOVA A, SALAK A N, et al. Zn-Al layered double hydroxides as chloride nanotraps in active protective coatings[J]. Corrosion Science, 2012, 55:1-4.
[54]	ZHELUDKEVICH M L, POZNYAK S K, RODRIGUES L M, et al. Active protection coatings with layered double hydroxide nanocontainers of corrosion inhibitor[J]. Corrosion Science, 2010, 52(2):602-611.
[55]	LI D D, WANG F Y, YU X, et al. Anticorrosion organic coating with layered double hydroxide loaded with corrosion inhibitor of tungstate[J]. Progress in Organic Coatings, 2011, 71(3):302-309.
[56]	YU D Y, WEN S G, YANG J X, et al. RGO modified ZnAl-LDH as epoxy nanostructure filler:a novel synthetic approach to anticorrosive waterborne coating[J]. Surface and Coatings Technology, 2017, 326:207-215.
[57]	NGUYEN T D, TRAN B A, VU K O, et al. Corrosion protection of carbon steel using hydrotalcite/graphene oxide nanohybrid[J]. Journal of Coatings Technology and Research, 2019, 16(2):585-595.
[58]	CHEN C L, HE Y, XIAO G Q, et al. Synergistic effect of graphene oxide@phosphate-intercalated hydrotalcite for improved anti-corrosion and self-healable protection of waterborne epoxy coating in salt environments[J]. Journal of Materials Chemistry C, 2019, 7(8):2318-2326.

Relative Articles

Supplements(0)

Cited By

Proportional views

Proportional views

通讯作者: 陈斌, bchen63@163.com

1.
沈阳化工大学材料科学与工程学院沈阳 110142

Get Citation

PDF

XML

Article Metrics

Article views (139) PDF downloads(18)

Research Progress in Application of Graphene Oxide Based Nanohybrid in Anti-corrosive Coatings

Abstract

References

Proportional views

Catalog

通讯作者: 陈斌, bchen63@163.com

Article Metrics

Proportional views

Related

Research Progress in Application of Graphene Oxide Based Nanohybrid in Anti-corrosive Coatings

Abstract

References

Proportional views

Catalog

通讯作者: 陈斌, bchen63@163.com

Article Metrics

Proportional views

Related

Export File

Citation

Format

Content