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Journal of Chinese Society for Corrosion and protection  2023, Vol. 43 Issue (6): 1237-1246    DOI: 10.11902/1005.4537.2022.351
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Research Progress on Carbon Dots in Field of Metal Corrosion and Protection
FAN Yufang1,2,3, ZHANG Yafei4, YIN Liusen1,2,3, ZHAO Conghui1,2,3, HE Yanbin1,2,3, ZHANG Chuanxiang1,2,3()
1.School of Chemistry and Chemical Engineering, Henan Polytechnic University, Jiaozuo 454003, China
2.Henan Key Laboratory of Coal Green Conversion, Jiaozuo 454000, China
3.Collaborative Innovation Center of Coal Safety Production and Clean and Efficient Utilization Jointly Built by the Ministry and the Province, Jiaozuo 454000, China
4.Ningbo Lvdong Fuel Cell Co., Ltd., Ningbo 315300, China
Cite this article: 

FAN Yufang, ZHANG Yafei, YIN Liusen, ZHAO Conghui, HE Yanbin, ZHANG Chuanxiang. Research Progress on Carbon Dots in Field of Metal Corrosion and Protection. Journal of Chinese Society for Corrosion and protection, 2023, 43(6): 1237-1246.

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Abstract  

How to avoid metal corrosion has became a key issure due to the widespread applications of various metals, therefore, it is urgent to develop the low toxicity and high-efficiency anticorrosive materials. Carbon dots (CDs), as a new zero-dimensional member of the carbon family, possesses the advantages of strong adsorption capacity, low toxicity, high solubility, good stability, and abundant surface functional groups, attract extensive attentions of researchers in the field of corrosion and protection of metallic materials. Herein, this work systematically elaborates the research progress of carbon dots especially as water-phase corrosion inhibitors and coating fillers. This review introduces corrosion inhibition effect about different heteroatom-doped carbon dots (nitrogen doped carbon dots, cerium and nitrogen co-doped carbon dots and nitrogen and sulfur co-doped carbon dots) on various metals. The corresponding corrosion inhibition mechanism can be summarized as that the protective film is formed through adsorption of CDs (physical adsorption or chemical adsorption) on surface of metals. Furthermore, we summarize the anti-corrosion mechanisms and research achievements of carbon dots as solvent-based and water-based coating fillers. By virtue of its small size and plentiful of functional groups, CDs can fill into micropores and fix the defects of coating so that to improve the comprehensive anti-corrosion performances of the composite coating. Finally, the challenges that carbon dots face in the field of corrosion and protection are also discussed.
Key words:  carbon dots      inhibitors      filler for coating      anticorrosion     
Received:  14 November 2022      32134.14.1005.4537.2022.351
ZTFLH:  TG174.4  
Fund: National Natural Science Foundation of China(52074109)
Corresponding Authors:  ZHANG Chuanxiang, E-mail: zcx223@163.com
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FAN Yufang
ZHANG Yafei
YIN Liusen
ZHAO Conghui
HE Yanbin
ZHANG Chuanxiang

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https://www.jcscp.org/EN/10.11902/1005.4537.2022.351     OR     https://www.jcscp.org/EN/Y2023/V43/I6/1237

Fig.1  Corrosion inhibition mechanism of N-CDs on carbon steel[56]
Fig.2  Morphologies of N-CDs1 (a), N-CDs2 (b),N-CDs3 (c) and schematic illustration of inhibition mechanism of N-CDs2 (d)[58]
Fig.3  Corrosion inhibition mechanism of N-CDs on Cu[69]
Fig.4  Corrosion inhibition experiment of Ce@N-CDs on carbon steel: (a) schematic representation of the protective mechanism, (b) Langmuir adsorption plot, (c) Tafel curves[61]
Raw materialsConcentration mg·L-1Corrosion mediumInhibition efficiencyReference
EDTA, PA, urea10015% HCl90%[75]
p-phenylenediamine2001 mol/L HCl88%[76]
Tryptophan2001 mol/L HCl96%[77]
Citric acid and L-histidine2001 mol/L HCl96%[78]
Citric acid and imidazole2001 mol/L HCl93%[79]
Citric acid and urea300.5 mol/L H2SO495%[80]
Ammonium citrate2001 mol/L HCl94%[81]
Methacrylic acid and n-butylamine2001 mol/L HCl95%[82]
Table 1  Corrosion inhibition efficiency of CDs
Fig.5  Corrosion inhibition mechanism of N,S-CDs on carbon steel (a) and Cu (b) [83,85]
Fig.6  Corrosion inhibition mechanism of N,S-CDs on Al (a) and Mg (b)[48, 87]
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