Highly reflective ZrC-Cu-based metal matrix composite coatings deposited via cold-spray for laser protection applications

[Display omitted] •First use of cold spray for composite coatings in anti-laser applications.•ZrC-Cu reflective coatings successfully deposited via cold spray process.•No ZrC decarburization or copper oxidation observed in coatings.•Cu-30 %ZrC achieved 85 % bulk copper reflectivity at 1080 nm wavele...

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Bibliographic Details
Published in:Optics and laser technology 2025-04, Vol.182, p.112171, Article 112171
Main Authors: Khan, Saiful Wali, Anupam, Ameey, Singla, Ekta, Singh, Harpreet
Format: Article
Language:English
Subjects:
Cold spray
Directed energy weapons
Laser ablation
Metal matrix composites
Reflective coatings
ZrC-Cu coatings
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Summary:[Display omitted] •First use of cold spray for composite coatings in anti-laser applications.•ZrC-Cu reflective coatings successfully deposited via cold spray process.•No ZrC decarburization or copper oxidation observed in coatings.•Cu-30 %ZrC achieved 85 % bulk copper reflectivity at 1080 nm wavelength.•All coatings, except Cu-85 %ZrC, resisted physical damage under laser tests. Lasers are very powerful and can produce high temperatures, capable of melting materials when projected with an appropriate power, exposure time, distance, and beam width. High energy lasers are used for attacking enemy aircraft and missiles; however, the same threat is inevitable to the allied aircraft and missiles. Surface coatings have proven to be a viable solution to reduce damage from such laser attacks. In the present work, ZrC-Cu-based highly reflective coatings were deposited on Al-6061 alloy using the cold spray to develop laser damage resistance. Microstructural characterization, XRD, micro-hardness, reflectivity measurements, and laser ablation tests were conducted on the developed materials. The results showed improved ceramic retention and mechanical properties along with minimal porosity in the coating with increasing ZrC content in the feedstock. Additionally, the XRD analysis revealed that Cu-ZrC composite coatings could be produced by cold spray, without decarburisation of ZrC or oxidation of Cu. Owing to the exceptional purity in coatings, highly reflective coatings were obtained. At the target wavelength of 1080 nm, Cu-30 %ZrC composition achieved a remarkable reflectivity of 75 % (85 % of bulk copper). The coatings with compositions of Cu-30 %ZrC, Cu-50 %ZrC and Cu-70 %ZrC remained undamaged under laser irradiation, whereas Cu-85 %ZrC exhibited a laser ablation pit. These findings provide valuable insights into developing optimized ZrC-Cu coatings against laser irradiation.
ISSN:0030-3992
DOI:10.1016/j.optlastec.2024.112171