Impurity Behavior in Cast Copper Anodes: Implications for Electrorefining in a Circular Economy

Impurity Behavior in Cast Copper Anodes: Implications for Electrorefining in a Circular Economy

The behavior of impurities in cast copper was investigated to simulate production with increased utilization of secondary sources within the framework of a circular economy. The incorporation of impurities, particularly Ni, Sn, and Sb, from recycled Cu may significantly impact the electrorefining pr...

Full description

Saved in:
Bibliographic Details
Main Authors: Agustin Morales-Aragon, Daniel Sánchez-Rodas, Guillermo Ríos, Michael S. Moats
Format: Article
Language:English
Published: MDPI AG 2025-01-01
Series:Metals
Subjects:
copper anodes
circular economy
nickel
tin
deportment
electron microscopy
Online Access:https://www.mdpi.com/2075-4701/15/2/113
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The behavior of impurities in cast copper was investigated to simulate production with increased utilization of secondary sources within the framework of a circular economy. The incorporation of impurities, particularly Ni, Sn, and Sb, from recycled Cu may significantly impact the electrorefining process. In this study, commercial anodes were doped with Ni, Sn, and Sb concentrations of 2500–6500 g/t, 300–900 g/t, and 450–950 g/t, respectively. Anode concentrations of Pb and Bi were maintained at 1000 g/t and 350 g/t, respectively. As concentrations were examined at two levels, 860 or 1700 g/t, depending on the commercial anode used to create the doped samples. Electron microscopy with microprobe analysis revealed that the commercial anodes contained three predominant phases: Cu<sub>2</sub>O, (Cu,Ag)<sub>2</sub>(Se,Te), and a complex oxide phase of Cu, Pb, As, Sb, and/or Bi. Ni, the main impurity, primarily accumulated within the Cu grains, while Sn and Sb tended to form oxidized inclusions. The distribution of Ni in Cu grains was ca. 20% lower in the anodes doped at higher Ni concentrations due to the formation of nickel-bearing inclusions, such as Kupferglimmer and NiO. The doped anodes showed lower quantities of Cu<sub>2</sub>O inclusions than the commercial anodes due to the preferential formation of oxides with other impurities, including SnO<sub>2</sub>. These findings highlight potential challenges for Cu electrorefining in a circular economy, as Ni, Sb, and Sn may impact the deportment of these impurities to slimes or electrolyte and may cause copper depletion in the refining electrolyte.
ISSN:2075-4701

Similar Items