International Journal of Metalcasting

, Volume 13, Issue 1, pp 130–136 | Cite as

Change of the Decorative Properties of Zinc-Plated Zinc Die Castings over Time

  • Valeriia Reveko
  • Felix Lampert
  • Grethe Winther
  • Per Møller


Zinc alloy die casting is often chosen for the manufacturing of various consumer goods, since this process allows manufacturing of parts with a consistent quality and a high cost efficiency. With regard to recycling, using zinc electrodeposition as a surface treatment for zinc die cast offers clear advantages. However, it is often noticed that bright zinc-plated coatings on zinc die cast components change color over time, developing distinct blue spots on the surface. In the present study, zinc-plated zinc die cast components were aged and characterized via Energy-Dispersive X-ray Spectroscopy, X-ray diffraction, and gloss and color analyses to make a conclusion on the mechanism of tarnishing. It was found that over time aluminum from the substrate diffuses through the coating, with the different diffusion rates for the coatings that were deposited from the different electrolyte types. Thus, alkaline zinc showed higher rates of aluminum diffusion compared to acid zinc. It was speculated that aluminum diffusion through the coating followed by oxidation under the influence of ambient moisture and contaminants triggers the observed blue discoloration.


electroplating zinc die cast zinc plating color change decorative surface finishing 



We thank Linimatic A/S for providing zinc die cast components for the testing, Vittorio Albertazzi for working on the color and gloss measurements, Flemming Bjerg Grumsen for assisting during the X-ray diffraction analysis and Niels Ulrik Gjerløff for the proof reading. We also gratefully acknowledge Martin Peter and Martin Netzer for industrial perspective contribution.


This work was done in the frame of Industrial PhD project at MTU MEK DTU supported by Collini GmbH (Project Number 76665, Task T-4).


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Copyright information

© American Foundry Society 2018

Authors and Affiliations

  1. 1.Collini GmbHHohenemsAustria
  2. 2.Materials and Surface Engineering, Department of Mechanical EngineeringTechnical University of DenmarkKongens LyngbyDenmark

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