Thermal Spray Coatings for Electromagnetic Wave Absorption and Interference Shielding: A Review and Future Challenges

“…For a specific coating product, several factors, such as their concentration/ viscosity, how the coating is applied, the salinity of seawater, exposure to sunlight, stress corrosion cracking processes, etc., determine their released quantity (Kirchgeorg et al, 2018). Thus, developing new forms of protection against corrosion based on eco-friendlier materials with intrinsic durability, good substrate adhesion and adequate mechanical properties is key to withstand external stresses, mechanical solicitation, or weathering while minimizing the release of toxic substances during their application and operation times (Faisal et al, 2022;Teijido et al, 2022).…”

Section: Future Opportunitiesmentioning

confidence: 99%

A perspective on nanocomposite coatings for advanced functional applications

Verma

Goel

2023

Nanofab

View full text Add to dashboard Cite

Functional coatings provide durability to the bulk material and add other value-added properties which enhance the surface's mechanical, electrical, optical, and many other properties. The functional response of these coatings stems from the ambiance, which can be made to sense in response to a sharp change in the temperature, pH, moisture, active ions, or mechanical stresses. Recently, many efforts have been made to impart multi-functionality within a single coating, i.e., to achieve hydrophobicity and antifouling characteristics, which can be achieved by combining an appropriate coating material with a geometric nanopattern. Such coatings are poised to shape the future of the transport, healthcare, and energy sectors, including marine, aeronautics, automobile, petrochemical, biomedical, electrical and electronic industries. This perspective sheds light on the design specifications and requirements to fabricate functional coatings and critically discusses the fabrication methods, working principles, and case studies to survey various applications with a particular focus on anti-corrosion and self-cleaning applications.

show abstract

“…Electromagnetic metamaterials are special periodic structures which are designed and fabricated artificially; their periodic unit cell is much smaller than the wavelength of EM waves. [10][11][12] Their electromagnetic properties primarily depend on the unit structure of the metamaterials and not entirely on the intrinsic properties of the material itself. Some recent studies have reported that the EAB can be effectively widened using electromagnetic metamaterials.…”

Section: Introductionmentioning

confidence: 99%

Ultra‐Broadband and Wide‐Angle Metamaterial Absorber with Carbon Black/Carbonyl Iron Composites Fabricated by Direct‐Ink‐Write 3D Printing

et al. 2023

View full text Add to dashboard Cite

This study proposes the fabrication of an asymmetric woodpile metamaterial absorber using direct-ink-writing 3D printing technology. The prepared inks are compounded using two loss fillers: carbon black and carbonyl iron powder. The synergistic effect enhances the electromagnetic loss performance and the synergistic mechanism is analyzed. The designed asymmetric woodpile absorber has a wider bandwidth than a simple tetragonal woodpile, and the advantage presented by the asymmetric woodpile arrangement overcomes the local impedance mismatch. A simulation is then performed, which demonstrates that the designed asymmetric woodpile metamaterial with a thickness of 8.6 mm can achieve a À10 dB absorbing bandwidth in the frequency range of 3.9-18 GHz, and the maximum reflection loss reaches up to À39 dB. Additionally, the absorber exhibits excellent angular performance and the absorption bandwidth of the transverse electric polarization or transverse magnetic polarization waves can reach more than 10 GHz with incident angles from 0°to 50°. Furthermore, the manufacturing process of the absorber is simple, efficient, and inexpensive, which presents considerable potential for its widespread implementation in practical engineering applications.

show abstract

Thermal Spray Coatings for Electromagnetic Wave Absorption and Interference Shielding: A Review and Future Challenges

Cited by 16 publications

References 203 publications

A coral-like nano-PCF composite as a broad-bandwidth microwave absorber

A coral-like nano-PCF composite as a broad-bandwidth microwave absorber

A perspective on nanocomposite coatings for advanced functional applications

Ultra‐Broadband and Wide‐Angle Metamaterial Absorber with Carbon Black/Carbonyl Iron Composites Fabricated by Direct‐Ink‐Write 3D Printing

Contact Info

Product

Resources

About