Corrosion Behaviour of Passive Layer Growth by Controlling Additives of Nano-Metals-Phosphate to Pure Aluminum

https://doi.org/10.24237/djes.2020.13401

Authors

  • Hussein A. Hussein Department of Production and Metallurgy Engineering, University of Technology, Baghdad – Iraq
  • Mohammed J. Kahdim Department of Production and Metallurgy Engineering, University of Technology, Baghdad – Iraq
  • Alaa Abdulhasan Atiyah Department of Materials Engineering, University of Technology, Baghdad – Iraq

Keywords:

Pure Aluminum, Passivity, Pitting corrosion and Nano-metals-phosphate

Abstract

This study investigates how microstructure and chemistry effects by Nano-Metal-Phosphate and the kinetics of growth passive layer and passivity breakdown. Additionally, the passive layer germination behavior on aluminum alloy 1050 with anticorrosive properties. The passive layer is an alloying method which allows an aluminum oxide to germinate. Morphologically and structurally, the aluminum oxide films were characterized using microscopy analyzes and XRD analysis. Results indicated that the reinforcements are well distributed and the grin size is downy. Corrosion behavior tested by Cyclic polarization exam and done at room temperature in (3.5 per cent NaCl) solution. The reinforcement increased the hardness for processed aluminum from Hv81.1 to HV=120.492 as castings. The parameter Nano-Metal-Phosphate has attenuated the current density of corrosion (7.15μA / cm2) compared to the as-cast sample results.

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Published

2020-12-09

How to Cite

[1]
H. A. Hussein, M. J. Kahdim, and A. A. Atiyah, “Corrosion Behaviour of Passive Layer Growth by Controlling Additives of Nano-Metals-Phosphate to Pure Aluminum”, DJES, vol. 13, no. 4, pp. 1–9, Dec. 2020.