IMPROVING THE CORROSION RESISTANCE OF MILD STEEL BY ZINC-GRAPHENE OXIDE COATINGS

被引:1
作者
Cotolan, Nicoleta [1 ]
Turdean, Graziella Liana [1 ]
Chelaru, Julieta Daniela [1 ]
机构
[1] Babes Bolyai Univ, Fac Chem & Chem Engn, 11 Arany Janos St, RO-400028 Cluj Napoca, Romania
来源
STUDIA UNIVERSITATIS BABES-BOLYAI CHEMIA | 2020年 / 65卷 / 03期
关键词
Graphene Oxide; Electrochemical Impedance Spectroscopy; Polarization Curves; Corrosion Resistance; Steel Corrosion;
D O I
10.24193/subbchem.2020.3.02
中图分类号
O6 [化学];
学科分类号
0703 ;
摘要
The main purpose of this work is to improve the corrosion resistance of steel substrates using the characterization of new composite zinc electrodeposits containing graphene oxides and reduced graphene oxide. The zinc-graphene based composite deposits were obtained by electrodeposition of an acidic electrolyte (pH = 5) at a current density of 20 mA/cm(2). Anionic surfactant (i.e., sodium dodecyl sulfate) was used to obtain uniform and compact coating morphology. Also, the investigated deposits had in their structure the graphene oxides produced by graphite exfoliation and the results concerning corrosion behavior of the zinc electrodeposits (Zn/S235 and Zngraphene/S235) were compared using the same experimental conditions. Microstructural characterization was carried out by SEM-EDS, whereas corrosion resistance was evaluated by EIS and polarization curves.
引用
收藏
页码:23 / 32
页数:10
相关论文
共 17 条
[1]   Optical investigation of reduced graphene oxide and reduced graphene oxide/CNTs grown via simple CVD method [J].
Allaedini, Ghazaleh ;
Mahmoudi, Ebrahim ;
Aminayi, Payam ;
Tasirin, Siti Masrinda ;
Mohammad, Abdul Wahab .
SYNTHETIC METALS, 2016, 220 :72-77
[2]   Electrochemically Exfoliated Graphene and Graphene Oxide for Energy Storage and Electrochemistry Applications [J].
Ambrosi, Adriano ;
Pumera, Martin .
CHEMISTRY-A EUROPEAN JOURNAL, 2016, 22 (01) :153-159
[3]  
Chelaru J.D., 2017, STUDIA UBB CHEM, V4, P357
[4]   Rapid thermal decomposition of confined graphene oxide films in air [J].
Chen, Xianjue ;
Meng, Dongli ;
Wang, Bin ;
Li, Bao-Wen ;
Li, Wei ;
Bielawski, Christopher W. ;
Ruoff, Rodney S. .
CARBON, 2016, 101 :71-76
[5]   Scanning tunneling microscopy and spectroscopy study of charge inhomogeneities in bilayer graphene [J].
Choudhary, Shyam K. ;
Gupta, Anjan K. .
SOLID STATE COMMUNICATIONS, 2011, 151 (05) :396-399
[6]   Fabrication and characterization of zinc-based superhydrophobic coatings [J].
Jain, R. ;
Pitchumani, R. .
SURFACE & COATINGS TECHNOLOGY, 2018, 337 :223-231
[7]   Exploring graphene as a corrosion protection barrier [J].
Kirkland, N. T. ;
Schiller, T. ;
Medhekar, N. ;
Birbilis, N. .
CORROSION SCIENCE, 2012, 56 :1-4
[8]   Electrochemical alternative to obtain reduced graphene oxide by pulse potential: Effect of synthesis parameters and study of corrosion properties [J].
Lopez-Oyama, A. B. ;
Dominguez-Crespo, M. A. ;
Torres-Huerta, A. M. ;
Onofre-Bustamante, E. ;
Gamez-Corrales, R. ;
Cayetano-Castro, N. .
DIAMOND AND RELATED MATERIALS, 2018, 88 :167-188
[9]   Electrodeposition of composite coatings containing nanoparticles in a metal deposit [J].
Low, C. T. J. ;
Wills, R. G. A. ;
Walsh, F. C. .
SURFACE & COATINGS TECHNOLOGY, 2006, 201 (1-2) :371-383
[10]   Laser-induced chemical transformation of free-standing graphene oxide membranes in liquid and gas ammonia environments [J].
Perez del Pino, A. ;
Gyorgy, E. ;
Cotet, C. ;
Baia, L. ;
Logofatu, C. .
RSC ADVANCES, 2016, 6 (55) :50034-50042
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