posted on 2023-10-05, 17:10authored byRiina Aromaa, Marja Rinne, Mari Lundström
Secondary hard metal contains valuable tantalum and niobium,
which
could be recovered after chemical recycling of the scrap; however,
the environmental impacts of their recycling have not been earlier
quantified. This study provides gate-to-gate life cycle inventory
data on tantalum and niobium recovery from the Ta–Nb-rich residue
after the leaching of cobalt in the chemical recycling of hard metal
and first assessment of the environmental impacts of tantalum and
niobium coproduction. The environmental impacts were quantified using
life cycle assessment (LCA) based on data acquired by process simulation.
Two processes were evaluated: one based on conventional HF leaching
used in the primary production of tantalum and niobium and one prospective
HF-free process using NaOH. The results show that environmental impacts
of Ta–Nb recycling can outperform primary production environmentally
if the Ta and Nb content in the raw material is high enough. At the
process level, a benefit is gained even with a lower content, but
at the product level, higher contents are required for tantalum recovery
to be worthwhile. In HF-based recycling, increasing the Ta and Nb
contents each from 2.5 to 5 wt % decreases the value of global warming
potential (GWP) of Ta recycling from 1.24 times the GWP of primary
tantalum production to 0.72 times the GWP of primary tantalum production.
The environmental impacts of the recycling processes mostly originate
from the background processes. The most burdening process hot spots
of recycling included the leaching and effluent treatment stages for
the HF-based process in which HF and lime were the largest contributors.
For the HF-free process, the largest contributions were due to NaOH
used in the caustic conversion as well as oxalic acid in the solvent
extraction.