Anticorrosion Applications Research Articles

Facile in-situ construction of multifunctional photothermal superhydrophobic composite membrane for effective anti-corrosion, anti-icing/de-icing and oil-water separation applications

Facile in-situ construction of multifunctional photothermal superhydrophobic composite membrane for effective anti-corrosion, anti-icing/de-icing and oil-water separation applications

Unveiling the potential of dual-extrinsic/intrinsic self-healing lignin-based coatings for anticorrosion applications

The development of self-healing ecofriendly coatings for anticorrosion applications provides stronger protection than passive coatings and mitigates the environmental pollution resulting from petroleum-derived coatings. Due to its intrinsic anticorrosion characteristics, lignin is a viable precursor for the formulation of self-healing anticorrosion coatings. However, the structural rigidity of lignin and the lack of self-healing functionalities in pristine lignin-based coatings hinder the comprehensive application of lignin in this field. Accordingly, we introduced Diels-Alder (DA)-based self-healing functions in the lignin-based coatings and meanwhile, the coatings were chemically conjugated with corrosion inhibitors to further improve the anticorrosion performance. A thin layer (16 μm) of the coating increased the Ecorr from −481 mV (for bare steel) to +91 mV and reduced the corrosion rate (CR) >4000 times. The dual self-healing properties of the coating are attributed to the synergistic action of the DA adduct and the conjugated corrosion inhibitor. Practically, in response to the emergence of microcracks in the coating structure, trace amounts of the corrosion inhibitor are released into the microcracks to form a protective layer on the unveiled metal surface. Simultaneously, DA adducts undergo reversible reactions at specific temperatures (80–120 °C) promoting complete restoration of the microcrack.

Preparation and performance study of self-repairing coating with superhydrophobic properties

Electricity has become one of the most important energy sources required for the operation of today’s society, and related electrical facilities are constantly being constructed. However, the environment in which electrical facilities are located is complex, how to protect their key components from corrosion has become an urgent problem to be solved. In this study, a kind of superhydrophobic coating with self-repairing properties was prepared based on polycarbonate polyurethane, which can be used to some extent as an anti-corrosion coating in electrical systems. A series of polyurethanes were prepared by adjusting the ratio of various crosslinkers, and the formula that can produce the best comprehensive performance was determined. Specifically, due to the action of disulfide bonds and hydrogen bonds, the prepared polyurethane can achieve a maximum fracture strength of 7.99 MPa and a fracture elongation of 749.19 %, while also having a self-repairing efficiency of 90.86 %. By spraying modified SiO2 to the surface, the polyurethane surface has excellent superhydrophobic properties, with a maximum WCA of 169.67°, and still maintains superhydrophobic properties after being worn for 2100 cm by 800 mesh sandpaper. And the coating also has excellent anti-corrosion property with protecting Q235 metal steel from corrosion in NSS test for 120 h. It has shown great potential in the anti-corrosion application of metal materials in electrical systems.

Amino-grafted Ti3C2 MXene nano-sheets doped with zinc-phytic acid complex; An advance 2D-nanocarrier toward improving epoxy coating smart anti-corrosion performance

MXene's unique structure and properties endow it with new applications in corrosion studies, drawing the attention of material scientists. In the present study, the MXene sheets modified by 3-Aminopropyltriethoxysilane (APTES) were utilized as carriers of zinc cations and phytic acid (Ph) (F-M@Zn-Ph) and then introduced into the epoxy coating for smart anti-corrosion application. Characterization tests such as X-ray Diffraction (XRD), Fourier Transform Infrared (FT-IR) Spectroscopy, X-ray Photoelectron Spectroscopy (XPS), Thermogravimetric Analysis (TGA), Field Emission Scanning Electron Microscopy (FE-SEM), Inductively Coupled Plasma Optical Emission Spectroscopy (ICP-OES), and zeta potential were carried out to validate the synthesis of F-M@Zn-Ph. The fabricated composite coatings' protective, and adhesion properties were studied by EIS, cathodic disbondment (CDT), salt spray (SST), and pull-off tests. Solution phase studies exhibited that the F-M@Zn-Ph sample inhibited mild steel corrosion up to 91 % during 48 h of immersion. Investigating the scratched coatings showed that the total resistance (RT) value for the F-M@Zn-Ph/EP sample enhanced by about 58 % compared to the Blank/EP during 48 h of immersion which denotes the self-healing properties of the coating. EIS results of the intact F-M@Zn-Ph/EP sample displayed the highest log|Z|0.01Hz value (10.83 Ω cm2) after 14 weeks of immersion. Along with the barrier properties improvement, the F-M@Zn-Ph/EP coating showed a small adhesion loss of 4 %.

(Invited) Aqueous Electrochemical Reduction Approaches for Functionalized Surfaces

To meet the demands of the green transition and mitigate climate change there is an increasingly urgent need for a wide range of crucial raw materials. Global resource scarcity, criticality, and supply disruption due to material shortfalls or geopolitical instability is driving efforts towards an inclusive, multi-materials circular economy with the objective of providing a more sustainable future. Within the domain of metals production, recent focus has been on development of new technological approaches that maximize the recovery of valuable materials, whilst simultaneously aiming at the reduction of the associated environmental impacts. In addition, the shift towards the increased use of lower grade input materials - either because of reduced ore quality or inclusion of secondary raw materials sources as feedstocks - often means there is a broader range of impurities within metallurgical process streams.In the case of industrial hydrometallurgical base metals—Cu, Ni, Zn—production methods like leaching, precipitation, and electrochemical reduction (electrorefining/electrowinning) impurities can include valuable metals like silver, gold, or platinum at such limited concentrations that conventional methods of recovery are often not economically viable. Moreover, the nature of hydrometallurgy process solution is that it is often contain highly concentrated levels of base metal (10’s g/l) - relative to the impurity materials (ppm/ppb) - that excludes the selective extraction of the valuable metals by conventional separation steps like solvent extraction, precipitation, cementation, or ion exchange. Consequently, there exists a need for alternative methods that can efficiently remove such low-level elements from complex solutions for recirculation or re-use.Over the last decade, two related electrochemical approaches have emerged as possible ways not only for the recovery of metals at low concentrations, but also for the creation of surfaces with additional functionality. The Electrodeposition-Redox Replacement (EDRR) methodology [1] exploits the cathodic reduction of less noble metal ions to electrodeposit a solid layer on an electrode surface by application of a constant or pulsed potential or constant current. This ED process is then followed by a period when the system is allowed to relax to its open circuit potential (OCP), which results in the spontaneous redox replacement (RR) of the deposited metal layer with more noble ions from the solution. These two steps - which can also be considered as sequential electrowinning-cementation - can be tailored to salvage different metals or produce different surfaces depending on the predominating base metal and the type of impurity within solution. For example, EDRR has been utilized to recover metals including Ag (from Zn process solutions), Au (from Cl leach solutions) and Te (from metallurgical industrial waste) as well as create surfaces with catalytic, anti-corrosion and analytical applications [1].More recently, the related Electrochemically-assisted Aqueous Reduction (EAR) method has emerged as an alternative approach to selectively recover Au from high concentration Cu chloride-based solutions[2]. In contrast to EDRR, this method uses a current or potential that is pulsed in order to reduce the copper ions in the solution proximal to the electrode from Cu(II) to Cu(I). This generated monovalent copper can then reduce the Au(III) or Au(I) present in solution due to their nobility difference. In situ studies performed with EQCM-D have allowed the influence of solution concentration changes and applied electrochemical parameters on the overall recovery process to be determined. Additionally, through the appropriate selection of the system boundaries, electrode surfaces decorated by gold nanoparticles could be created demonstrating that EAR can be used to electrochemically prepare noble metal surfaces with the potential for additional functionalities like electrochemical ethanol oxidation from complex process solutions.Overall, both EDRR and EAR offer alternative and efficient methods that allow not only for the recovery of trace levels of valuable metals from under exploited hydrometallurgical solutions, but these approaches also provide the potential to directly create materials with a range of surface functionalized materials. Furthermore, EDRR is already being exploited on an industrial scale [3] to enhance energy efficiency, improve materials circularity and process economics in a range of applications. Acknowledgments This work was supported by the Research Council of Finland project EARMetal (#339979 and #342080). The RawMatTERS Finland Infrastructure (RAMI) also funded by the Research Council of Finland and based at Aalto University is acknowledged.

Synthesis and application of Aromatic Schiff base waterborne polyurethane as visible-light triggered self-healing polymer and anticorrosion coating using h-BN/GO/NiO nano-composite

Herein, a self-healing waterborne polyurethane (WPU) based on a novel visible light-stimulated healing agent from the aromatic Schiff base family (SBWPU) was synthesized. Moreover, this polymer exhibited remarkable mechanical properties, making it an ideal matrix for the preparation of a new nano-composite coating using hexagonal-boron nitride/graphene oxide/nickel oxide (h-BN/GO/NiO) nano-composite for anti-corrosion applications. SBWPU containing 15 wt % of synthesized healing agent (SBWPU-15) demonstrated favorable healing properties (80.03 %) under a visible light lamp after 24 h (at ambient temperature). SBWPU containing 20 % of the healing agent (SBWPU-20) showed high mechanical properties (20.80 MPa) and an increase in its hydrophobic properties. Additionally, its water absorption rate decreased, making it an attractive option as a polymer matrix for anti-corrosion coating applications. The nano-composite coatings (CSBWPU) were formulated by introducing varying amounts of h-BN/GO/NiO into the SBWPU-20. The coatings displayed an increase in contact angle and a decrease in water absorption rate. The electrochemical impedance spectroscopy (EIS) results revealed that the 0.75-CSBWPU, containing 0.75 % nano-composite, had the highest corrosion resistance (1.58 × 1010 Ω cm2) after 90 days of immersion in seawater. This work offers a potentially helpful concept for developing an eco-friendly, secure, uncomplicated accessibility self-healing polymeric system with controllable mechanical features, which are also favorable for designing novel corrosion protection composite coatings.

Bio-inspired sustainable benzoxazine based composites containing aniline derivatives: A comprehensive study on anti-microbial, advanced coatings, oil-water separation and electronic utilizations

A comprehensive study of benzoxazines derived from magnolol and five different substituted aniline moieties through Mannich condensation was carried out. The structural confirmation was ascertained using different spectral analyses. Mg-a exhibited a lowest polymerization temperature of 220 °C than that of other monomers. Whereas, poly (Mg-ea) showed relatively the higher initial thermal stability until 411 °C with char yield of 56 % at 850 °C and enhanced values of limiting oxygen index (LOI) and statistic heat resistance index (HRI) than rest of polybenzoxazines. The Mg-pfa benzoxazine monomer exhibits significant antibacterial behavior with a maximum of 22 mm zone of inhibition and less cytotoxicity with IC50 value of 162 μg/ml as well as better corrosion resistant properties with 99 % corrosion inhibition efficiency. The hydrophobic studies indicated that poly (Mg-tfa) exhibited the highest water contact angle (CA) value of 143°. Poly (Mg-tfa) coated cotton fabric was resistant to chemical and UV treatments along with the 97 % of oil water separating efficiency. Polybenzoxazine composites were derived from poly (Mg-fa) matrix and cashew nut shell residue ash (CNA) and cashew nut shell carbon (CNC) fillers to ascertain influence on thermal, dielectric and hydrophobic properties. Poly (Mg-fa) composites reinforced with 15 wt% of CNA and 15 wt% of CNC exhibited dielectric constant values of 2.71 and 6.91 respectively at a frequency of 1 MHz. Findings from multifaceted studies indicate that the polybenzoxazines and composites reported in the present work can be utilized for anti-corrosion, anti-microbial, oil-water separation and electronic applications for improved performance and enhanced longevity.

Models for the Design and Optimization of the Multi-Stage Wiredrawing Process of ZnAl15% Wires for Spray Metallization.

Metallization, a process for applying anti-corrosion coatings, has advantages over hot-dip galvanizing, such as reduced thermal stress and the ability to work "in situ". This process consists of the projection of a protective metal as coating from a wire as application material, and this wire is obtained by multi-stage wiredrawing. For the metallization process, a zinc-aluminum alloy wire obtained by this process is used. This industrial process requires multiple stages/dies of diameter reduction, and determining the optimal sequence is complex. Thus, this work focuses on developing models with the aim of designing and optimizing the wiredrawing process of zinc-aluminum (ZnAl) alloys, specifically ZnAl15%, used for anti-corrosion applications. Both analytical models and numerical models based on the finite element method (FEM) and implemented by computer-aided engineering (CAE) software Deform 2D/3D v.12, enabled the prediction of the drawing stress and drawing force in each drawing stage, producing values consistent with experimental measurements. Key findings include the modeling of the material behavior when ZnAl15% wires were subjected to the tensile test at different speeds, with strain rate sensitivity coefficient m = 0.0128, demonstrating that this type of alloy is especially sensitive to the strain rate. In addition, the optimal friction coefficient (µ) for the drawing process of this material was experimentally identified as µ = 0.28, the ideal drawing die angle was determined to be 2α = 10°, and the alloy's deformability limit has been established by a reduction ratio r ≤ 22.5%, which indicates good plastic deformation capacity. The experimental results confirmed that the development of the proposed models can be feasible to facilitate the design and optimization of industrial processes, improving the efficiency and quality of ZnAl15% alloy wire production.

Investigation of the Anticorrosive Activity of Piper divaricatum Essential Oil on Steel in 1 M HCl.

Piper divaricatum essential oil (PDEO), extracted from plants of the Brazilian Amazon, was investigated for the first time as a novel green or eco-friendly inhibitor for steel corrosion in 1 M HCl at 25 °C. Our electrochemical studies demonstrate that for different PDEO concentrations, lower E corr and i corr values were obtained. The influence of the oil concentration on corrosion inhibition, 0.5-4 g/L, was determined for 1 and 7 days of immersion. The corrosion rate (CR) and inhibition efficiency (IE) were determined by mass loss. The steel surface in the presence and absence of oil was investigated by scanning electron microscopy (SEM). The main PDEO compounds, determined by gas chromatography-mass spectrometry (GC-MS), were methyleugenol (20.68%) and eugenol (15.42%). The CR and IE for 2 g/L PDEO exhibited an optimal value of 4.31 mm/year and 98.3% for 7 days of immersion, respectively. The surface with 2 g/L oil for 7 days exhibited a less rough morphology, which was attributed to the corrosion inhibitory effect of PDEO. In addition, the PDEO adsorption process on the steel surface obeyed the Langmuir isotherm model. Negative values found for free standard energy ( < 0 kJ·mol-1) were attributed as a favorable process, i.e., an indicative of physisorption and chemisorption between the PDEO components and the steel surface. Our results reveal that the PDEO has a promising character for anticorrosive steel applications and metal coating in industries.

Corrosion protection performance of poly(PyM-co-GMA)/SWCNT nanocomposites coating on mild steel

Recently, there has been significant emphasis on developing electroactive functional methacrylate polymers for anticorrosive applications. In this context, we have synthesized Poly[(3,5-dimethyl-1H-pyrazole-1-yl) methyl methacrylate-co-glycidyl methacrylate] [Poly(PyM-co-GMA)] and its nanocomposite with single- walled carbon nanotubes (SWCNTs) [Poly(PyM-co-GMA)/SWCNT]. The resulting materials were characterized using Fourier Transform Infrared spectroscopy (FT-IR) and X-ray Diffraction analysis (XRD). Morphological changes due to the incorporation of SWCNTs were examined using field-emission scanning electron microscopy (FE-SEM) and high-resolution transmission electron microscopy (HR-TEM). The optical properties of Poly(PyM-co-GMA) and Poly(PyM-co-GMA)/SWCNT (0.5, 1.0, and 1.5 wt. %) were investigated. The thermal behavior of Poly(PyM-co-GMA) and its SWCNT nanocomposites was analyzed through thermogravimetric analysis (TGA). The anticorrosive performance of the prepared materials was evaluated on a mild steel substrate (MS) in a 3.5% (w/v) NaCl medium using electrochemical techniques. Results from potentiodynamic polarization and electrochemical impedance spectroscopy indicate that the Poly(PyM-co-GMA) and Poly(PyM- co-GMA)/SWCNT coatings (0.5, 1.0, and 1.5 wt. %) provide effective barrier protection for mild steel against marine environments.

Enhanced photocathodic protection performance of TiO2/SnO2/CdIn2S4 composites for 304 stainless steel in marine environments

In humid and saline environments, metal corrosion leads to significant economic losses, necessitating enhanced anti-corrosion methods. This study aims to enhance the photocathodic protection (PCP) performance of TiO2 nanotubes (NTs) by incorporating SnO2 quantum dots (QDs) and CdIn2S4 nanoflowers (NFs). TiO2 NTs were fabricated on titanium substrates via anodization, followed by successive deposition of SnO2 QDs and CdIn2S4 NFs using immersion and hydrothermal methods. The composite materials were characterized using SEM, TEM, XRD, and XPS. The PCP performance was evaluated through electrochemical tests on 304 stainless steel (304ss). The TiO2/SnO2/CdIn2S4 (T/S/C) composite exhibited a photocurrent density seven times that of pure TiO2 NTs, indicating significantly enhanced separation ability. The composite also demonstrated a notable open-circuit potential (OCP) of −1045 mV vs. SCE. Furthermore, T/S/C could provide delayed protection for up to 10 h in the dark, indicating its electron storage capability. The T/S/C composite material enhances the corrosion resistance of 304ss, offering a promising approach for practical anti-corrosion applications.

Scalable and durable polydimethylsiloxane coating for anti-corrosion, anti-fouling, and condensation applications

Scalable and durable polydimethylsiloxane coating for anti-corrosion, anti-fouling, and condensation applications

Recent Developments in the Fabrication and Application of Superhydrophobic Suraces.

A superhydrophobic surface is defined as having a contact angle exceeding 150 °C, indicating a remarkable ability to repel water. Generally, superhydrophobicity originates from the utilization of low-surface-energy materials with unique micro- and nanostructures. Superhydrophobic surfaces have gained considerable recognition and are widely employed in diverse areas for anti-icing, oil-water separation, anticorrosion, self-cleaning, blood-repellent, and antibacterial applications. These surfaces can greatly enhance industrial processes by yielding significant performance improvements. In this review, we introduce the basic theories that provide a foundation for understanding the hydrophobic properties of superhydrophobic surfaces. We then discuss current techniques for fabricating superhydrophobic coatings, critically analyzing their strengths and limitations. Furthermore, we provide an overview of recent progress in the application of superhydrophobic materials. Finally, we summarize the challenges in developing superhydrophobic materials and future trends in this field. The insights provided by this review can help researchers understand the basic knowledge of superhydrophobic surfaces and obtain the latest progress and challenges in the application of superhydrophobic surfaces. It provides help for further research and practical application of superhydrophobic surfaces.

A facile preparation of durable superhydrophobic PFA coatings with superior anti-icing, anti-corrosion and self-cleaning performance

The potential of superhydrophobic coatings for various applications has been widely recognized. However, preparing durable superhydrophobic coatings on metal surfaces remains a significant challenge. Perfluoroalkoxy Alkane (PFA), a fluorine-rich material, has recently emerged as a promising candidate for constructing superhydrophobic coatings. In this study, a mechanically stable superhydrophobic PFA coating was prepared using a simple combination of electrodeposition and annealing. The prepared PFA coating displays excellent water repellency, as evidenced by a water contact angle of 171 ± 0.3° and a sliding angle of 1.0 ± 0.4° The water contact angle of the coating only decreases by 0.6°after undergoing 400 tape stripping tests, indicating the remarkable stability. The PFA coating significantly prolongs the freezing time of water droplets on a cool surface at temperatures of -6 °C, -8 °C, and -10 °C, with improvements of 19.4, 72.5, and 47.8 times respectively. The corrosion current density on the coated surface is reduced by four orders of magnitude compared to bare aluminum alloy, and the PFA coating exhibits a high inhibition corrosion efficiency of 99.995 %. Furthermore, the coating possesses exceptional self-cleaning performance by repelling dirt particles and maintaining a clean surface. Consequently, the developed superhydrophobic PFA coating holds significant promise for long-lasting anti-icing, anti-corrosion and self-cleaning applications.

Exfoliated MoS2 with tunable size effect towards anticorrosion application

MoS2 sheets are becoming more and more active in the field of anticorrosion coatings. In this work, different size of MoS2 were fabricated by a simple gradient centrifugation approach then introduced into epoxy coatings (EP). Composite coatings with smaller size and larger size of MoS2 were also prepared for comparison. Anticorrosion properties of the coatings were evaluated via electrochemical spectroscopy, salt spray tests and theoretical calculation in detail. The impedance arc of doping the 1.4±0.1 μm of EM2000 for EP was 4.8×107 Ω cm2 after 7d immersing, which is much higher than that of EM800/EP, EM1000/EP and EM3000/EP. Salt spray test and corrosion products analysis have also proved the proposed protection mechanism of EM2000/EP coating. Doping the optimized size of EM2000 could form nano-network covering the microcracks to impede the diffusion of corrosive medium. In addition, the theoretical calculation showed that the body-center adsorption of O2 show the weaker physisorption with adsorption energies of ∼ −0.64 eV and −0.14 eV for H2O and O2. Excellent barrier ability and enhanced dispersion of the optimized size of MoS2 sheets were responsible for the superior enhancement of the anticorrosion performance of EP coating.

Robust superhydrophobic micro-nanostructures design based on polarity-opposite amorphous polymers

Superhydrophobicity exhibited by several natural surfaces has broad application prospects due to their excellent self-cleaning and low adhesion properties. However, designing a robust superhydrophobic coating via design strategy using amorphous polymers is allimportant for industrial applications, yet rather challenging. Here, we report a scalable strategy based on the phase separation and swelling treatment to construct an ultra-durable superhydrophobic coating with hierarchical micro-/nanostructures formed by two amorphous polymers (e.g. hydrophilic and lipophilic polymers). The controlled phase separation of two amorphous polymers creates uniformly distributed microprotrusions on the coating surface and the following swelling process produces submicro-/nanobumps on the microprotrusions. Notably, when both types of polymers achieve the hierarchical micro-/nanostructures, hydrophilic polymers exhibit strong adhesion with the substrates, whereas lipophilic polymers reduce the surface energy of the system. Benefitting from the self-similar structure and the adhesive effect, the polymer-based superhydrophobic coating displays superior mechanical and chemical robustness. Furthermore, our strategy will boost the practical application of robust superhydrophobic coatings for anti-corrosion application.

Exploring novel anticorrosive applications: Solid-state synthesis and characterization of Li2CuP2O7 and Na2CuP2O7 pyrophosphates

This work shows the importance of inorganic materials Li2CuP2O7 and Na2CuP2O7, especially the effect of Li and Na atoms, in their use as inhibitors that preserve Mild steel in 1.0 M HCl solution. Lithium and Sodium copper (II) pyrophosphate crystals were synthesized through solid-state reaction and characterized using Infrared Spectroscopy technique (IR), as well as X-ray diffraction (XRD). The infrared spectrum of compounds Li2CuP2O7 and Na2CuP2O7 was captured and interpreted, revealing a bent POP bridging angle within these compounds. Furthermore, the inhibitory effect of these pyrophosphates on Mild steel corrosion in a 1.0 M HCl solution was studied. During this investigation, electrochemical techniques alongside surface examination through SEM and EDX. The experimental findings demonstrated that Li2CuP2O7 and Na2CuP2O7 act as effective inhibitors, with inhibition efficiency (ηPP%) rising as the inhibitor concentration increases. At a concentration of 10−3 M, Li2CuP2O7 exhibited a remarkable inhibition efficiency of 93 %, which appears to be mixed-type inhibitors.

A self-healing polyurethane/imidazole-modified carboxylated graphene oxide composite coating for antifouling and anticorrosion applications

Marine corrosion and biofouling present significant challenges to maintaining maritime vessels and oceanic infrastructure. Developing coatings that integrate anti-fouling, anti-corrosion, and self-healing properties remains a critical issue. This study introduces imidazolium-modified carboxylated graphene (FCGO) into polyurethane coatings (F-PUSS) containing disulfide bonds to address this challenge. The incorporation of FCGO significantly enhances the mechanical properties of the coating, improving tensile stress by 40 % to 20.97 MPa. The barrier properties of FCGO also provide strong corrosion resistance, with |Z|0.01Hz values an order of magnitude higher than the original samples, even after 15 days of immersion in sodium chloride (3.5 wt%). Additionally, F-PUSS retains corrosion resistance after repairs. The synergistic action of imidazole groups and graphene provides excellent antifouling performance with nearly to an alga rate of 100 % and an antimicrobial rate of 96 %. F-PUSS demonstrates remarkable self-healing capabilities, with a healing efficiency of 78 % after 48 h at 60 °C. This study provides valuable insights for designing multifunctional polymer materials with anti-fouling, anti-corrosion, and self-healing functions.

One-step fabrication of robust PDMS-MWCNTs composite superhydrophobic coatings with hierarchical micro-nanostructures for anticorrosive applications

Superhydrophobic coatings hold considerable promise for safeguarding metals against corrosion. However, realizing coatings with excellent superhydrophobicity, mechanical strength and corrosion resistance remains a great challenge. In this study, a robust superhydrophobic surface was achieved through the laser processing of multi walled carbon nanotubes (MWCNTs)/polydimethylsiloxane (PDMS) coatings, resulting in a water contact angle (WCA) of approximately 165°. Notably, the coating demonstrated outstanding abrasion resistance in sandpaper abrasion, steel wool abrasion, and falling sand tests. The friction coefficient of the coating is only 0.25. In addition, the robust superhydrophobic coating also has good anti-corrosion. The lowest-frequency impedance value of the composite coatings increases seven orders of magnitude compared with that of carbon steel, and the corrosion inhibition efficiency (η) is 99.83 %. The outstanding corrosion resistance is primarily ascribed to the formation of a dual synergistic barrier by PDMS-MWCNTs, providing effective protection for carbon steel.

Two-Dimensional Metal-Organic Frameworks/Epoxy Composite Coatings with Superior O2/H2O Resistance for Anticorrosion Applications.

Corrosion protection technology plays a crucial role in preserving infrastructure, ensuring safety and reliability, and promoting long-term sustainability. In this study, we combined experiments and various analyses to investigate the mechanism of corrosion occurring on the epoxy-based anticorrosive coating containing the additive of two-dimensional (2D) and water-stable zirconium-based metal-organic frameworks (Zr-MOFs). By using benzoic acid as the modulator for the growth of the MOF, a 2D MOF constructed from hexazirconium clusters and BTB linkers (BTB = 1,3,5-tri(4-carboxyphenyl)benzene) with coordinated benzoate (BA-ZrBTB) can be synthesized. By coating the BA-ZrBTB/epoxy composite film (BA-ZrBTB/EP) on the surface of cold-rolled steel (CRS), we found the lowest coating roughness (RMS) of BA-ZrBTB/EP is 2.83 nm with the highest water contact angle as 99.8°, which represents the hydrophobic coating surface. Notably, the corrosion rate of the BA-ZrBTB/EP coating is 2.28 × 10-3 mpy, which is 4 orders of magnitude lower than that of the CRS substrate. Moreover, the energy barrier for oxygen diffusion through BA-ZrBTB/EP coating is larger than that for epoxy coating (EP), indicating improved oxygen resistance for adding 2D Zr-MOFs as the additive. These results underscore the high efficiency and potential of BA-ZrBTB as a highly promising agent for corrosion prevention in various commercial applications. Furthermore, this study represents the first instance of applying 2D Zr-MOF materials in anticorrosion applications, opening up new possibilities for advanced corrosion-resistant coatings.