Lithium-ion battery
demand, particularly for electric vehicles,
is projected to increase by over 300% throughout the next decade.
With these expected increases in demand, cobalt (Co)-dependent technologies
face the risk of significant impact from supply concentration and
mining limitations in the short term. Increased extraction and secondary
recovery form the basis of modeling scenarios that examine implications
on Co supply to 2030. Demand for Co is estimated to range from 235
to 430 ktonnes in 2030. This upper bound on Co demand in 2030 corresponds
to 280% of world refinery capacity in 2016. Supply from scheduled
and unscheduled production as well as secondary production is estimated
to range from 320 to 460 ktonnes. Our analysis suggests the following:
(1) Co price will remain relatively stable in the short term, given
that this range suggests even a supply surplus, (2) future Co supply
will become more diversified geographically and mined more as a byproduct
of nickel (Ni) over this period, and (3) for this demand to be met,
attention should be paid to sustained investments in refined supply
of Co and secondary recovery.
Materials criticality assessment is a screening framework increasingly applied to identify materials of importance that face scarcity risks. Although these assessments highlight materials for the implicit purpose of informing future action, the aggregated nature of their findings make them difficult to use for guidance in developing nuanced mitigation strategy and policy response. As a first step in the selection of mitigation strategies, the present work proposes a modeling framework and accompanying set of metrics to directly compare strategies by measuring effectiveness of risk reduction as a function of the features of projected supply demand balance over time. The work focuses on byproduct materials, whose criticality is particularly important to understand because their supplies are inherently less responsive to market balancing forces, i.e., price feedbacks. Tellurium, a byproduct of copper refining, which is critical to solar photovoltaics, is chosen as a case study, and three commonly discussed byproduct-relevant strategies are selected: dematerialization of end-use product, byproduct yield improvement, and end-of-life recycling rate improvement. Results suggest that dematerialization will be nearly twice as effective at reducing supply risk as the next best option, yield improvement. Finally, due to its infrequent use at present and its dependence upon long product lifespans, recycling end-of-life products is expected to be the least effective option despite potentially offering other benefits (e.g., cost savings and environmental impact reduction).
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