A novel superhydrophobic Ni/Nip coating fabricated by magnetic field induced selective scanning electrodeposition

Shen, Lida; Xu, Mingyang; Jiang, Wei; Qiu, Mingbo; Fan, Mingzhi; Ji, Guangbin; Tian, Zongjun

doi:10.1016/j.apsusc.2019.05.335

Cited by 46 publications

(14 citation statements)

References 40 publications

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“…However, the two points signified that the electrodeposition process's magnetic field application is significant in controlling coating morphology. Shen et al [119] added ferromagnetic nano-nickel particle (Nip) of 500 nm in diameter in a platting solution and generated a magnetic field that was parallel by introducing into the electromagnet a constant DC, as shown in (Figure 12). It was a Ni/Nip anti-corrosive superhydrophobic coating on copper by magnetic field-induced scanning electrodeposition.…”

Section: Magnetic Field-inducedmentioning

confidence: 99%

See 1 more Smart Citation

Superhydrophobic Coating Fabrication for Metal Protection Based on Electrodeposition Application: A Review

Miller¹,

Hu²,

Weamie³

et al. 2021

MSCE

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In recent years, superhydrophobic media has attracted tremendous attention due to its industrial applicability value, especially in anti-corrosion performance. The superhydrophobic coating, which has a robust and water-repellent capacity, can catch the air to form several "airbags" on the substrate's surface, isolating the corrosion media. Various superhydrophobic coating preparation technologies have been suggested, but each has its own set of flaws. On the other hand, electrodeposition, as a relatively mature industrial processing application, offers distinct advantages. However, until now, there have been few reviews on the electrodeposition preparation of anticorrosive superhydrophobic coatings. Therefore, the author has described several fabrication techniques based on superhydrophobic coatings in this review, including the advantages and disadvantages. Superhydrophobic coatings conventional concepts and wettability, as well as the model wetting concepts, have been reviewed. The coating processing status and the corrosion-resistant potential through the electrodeposition of metal and comparable composite are detailly encapsulated. Furthermore, electrodeposition parameters, including current density, crystal modifiers, and a deposition time of the coating morphology, are reported, following the ultrasonic-assisted, jet, pulse, and magnetic field-induced electrodeposition, respectively, as the recently developed technologies for preparing a coating. Finally, technology limitation is shown as well as the obstacles and prospects, and the improvement of the superhydrophobic coating's durability as a prospects research focus has been recommended.

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Section: Magnetic Field-inducedmentioning

confidence: 99%

“…The presence of the magnetic field deposition on the cathode surface developed a uniform micron-nanometer layered structure, and Figure 12. A magnetic field induced electrodeposition technology imagery [119].…”

Section: Magnetic Field-inducedmentioning

confidence: 99%

Superhydrophobic Coating Fabrication for Metal Protection Based on Electrodeposition Application: A Review

Miller¹,

Hu²,

Weamie³

et al. 2021

MSCE

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“…Superhydrophobic surfaces are gaining more and more research attention due to their great properties of anticorrosion [ 5 , 6 , 7 ], drag reduction [ 8 , 9 , 10 ], self-cleaning [ 11 , 12 ] and anti-icing [ 13 ]. Many methods to prepare superhydrophobic surfaces have been investigated, which mainly include chemical etching [ 14 ], electrodeposition [ 15 ], laser engraving [ 16 ], anodizing [ 17 , 18 ] etc. The excellent performance of superhydrophobic surfaces offer potential applications in many fields, such as microfluidic control [ 19 ], corrosion inhibition [ 20 ], nondestructive transportation [ 21 ], drag reduction [ 22 ], and so on.…”

Section: Introductionmentioning

confidence: 99%

A Facile Method to Prepare a Superhydrophobic Magnesium Alloy Surface

Zhu

Jia

2020

Materials

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The application of superhydrophobic materials has been handicapped by complex processes and poor environmental friendliness. Magnesium alloys are widely used in daily production due to their low density and good casting properties. A facile and environmentally friendly method was proposed to prepare a superhydrophobic layer with coral-like microstructure on the surface of AZ91D magnesium alloy by high temperature heating. The prepared superhydrophobic surface has a contact angle of 159.1° and a rolling angle of 4.8°. The corrosion current of superhydrophobic surface has been reduced by about two orders of magnitude relative to the magnesium alloy substrate and its inhibition efficiency is 96.94%, which demonstrates its great corrosion resistance. In addition, the superhydrophobic surface has great thermal stability. When the temperature rises to 190 °C, the contact is still above 150°. Excellent self-cleaning and advantages in preparation efficiency, environmental protection and cost-effectiveness will boost its good application prospects.

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“…In fact, they are very common in nature, such as lotus leaves, [ 12 ] rose petals, [ 13 ] butterfly wings, [ 14 ] and bird feathers. [ 15 ] Many scientists have investigated the construction mechanism of superhydrophobic surfaces based on the research of Barthlott and Neinhuis, [ 16 ] finding that the superhydrophobic surface can expand the application of materials in corrosion resistance, [ 17 ] oil–water separation, [ 18,19 ] antifouling, [ 20 ] anti‐icing, [ 21 ] and antibacterial, [ 22 ] etc. Until now, many methods have been used to construct superhydrophobic surfaces on stainless steels, such as electrodeposition, [ 23 ] hydrothermal treatment, [ 24 ] sol–gel processing, [ 25 ] etching, [ 26 ] dip coating, [ 27 ] and so on.…”

Section: Introductionmentioning

confidence: 99%

Fabrication of a Robust Superhydrophobic Ni Coating with Micro–Nano Dual‐Scale Structures on 316L Stainless Steel

et al. 2020

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Herein, a superhydrophobic Ni coating is prepared on 316L stainless steel by electrodeposition and low energy modification with tetradecanoic acid. After 20 min of electrodeposition with a current density of 8 A dm−2, a Ni coating with micro–nano dual‐scale structures is obtained. The coating becomes superhydrophobic with a water contact angle (WCA) of 160.4° and a sliding angle (SA) of 8.3° after being immersed in the tetradecanoic acid solution (5 g L−1, 12 h). A two‐level structure model is established for explaining the effect of morphology on the wettability of the coating. The WCA value of the superhydrophobic Ni coating retains above 150° after being exposed in outdoor environment for 6 months and in flowing environment for 7 days. In addition, the coating still shows superhydrophobicity after 9 times of mechanical abrasion test, 12 h of acid soaking (pH = 1), and 16 h of heat treatment in 200 °C. Moreover, the coating improves the corrosion resistance of the steel substrate. This superhydrophobic Ni coating provides a simple method to prevent stainless steel from corrosion. And the theoretical calculation of the two‐level model can provide an innovative strategy for designing the structure of the superhydrophobic coating.

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A novel superhydrophobic Ni/Nip coating fabricated by magnetic field induced selective scanning electrodeposition

Cited by 46 publications

References 40 publications

Superhydrophobic Coating Fabrication for Metal Protection Based on Electrodeposition Application: A Review

Superhydrophobic Coating Fabrication for Metal Protection Based on Electrodeposition Application: A Review

A Facile Method to Prepare a Superhydrophobic Magnesium Alloy Surface

Fabrication of a Robust Superhydrophobic Ni Coating with Micro–Nano Dual‐Scale Structures on 316L Stainless Steel

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