Abstract
Many new and efficient technologies require ‘critical metals’ to function. These metals are often extracted as by-product of another metal, and their future supply is therefore dependent on mining developments of the host metal. Supply of critical metals can also be constrained because of political instability, discouraging mining policies, or trade restrictions. Scenario analyses of future metal supply that take these factors into account would provide policy makers with information about possible supply shortages. We provide a scenario analysis for demand and supply of cobalt, a potentially critical metal mainly used not only in high performance alloys but also in lithium-ion batteries and catalysts. Cobalt is mainly extracted as by-product of copper and nickel. A multiregional input–output (MRIO) model for 20 world regions and 163 commodities was built from the EXIOBASE v2.2.0 multiregional supply and use table with the commodity technology construct. This MRIO model was hybridized by disaggregating cobalt flows from the nonferrous metal sector. Future cobalt demand in different world regions from 2007 to 2050 was then estimated, assuming region- and sector-specific GDP growth, constant technology, and constant background import shares. A dynamic stock model of regional reserves for seven different types of copper, cobalt, and nickel resources, augmented with optimization-based region-specific mining capacity estimates, was used to determine future cobalt supply. The investment attractiveness index developed by the Fraser Institute specifically for mining industry entered the optimization routine as a measure of the regional attractiveness of mining. The baseline scenario shows no cobalt supply constraints over the considered time period 2007–2050, and recovering about 60 % of cobalt content of the copper and nickel ore flows would be sufficient to match global cobalt demand. When simulating a hypothetical sudden supply dropout in Africa during the period 2020–2035, we found that shortages in cobalt supply might occur in such scenarios.
Highlights
Almost all elements of the periodic table are used in modern technology, especially for renewable energy and communication technologies
1.4 Scope This paper focuses on the global demand for and supply of cobalt, a potentially critical metal mainly used in high performance alloys and in lithium-ion batteries and catalysts
Cumulative cobalt demand in ore that needs to be extracted for the period 2007–2050 amount to about 6300 ktons, which is about 40 % of the estimated total cobalt reserves of 16 Mt that are known and recoverable, mostly from copper and nickel mines (Mudd et al 2013)
Summary
Almost all elements of the periodic table are used in modern technology, especially for renewable energy and communication technologies. Graedel et al assessed the Tisserant and Pauliuk Economic Structures (2016) 5:4 performance of potential substitutes for all major applications of the different elements (Greenfield and Graedel 2013) Their central finding is that no element can be completely replaced by others, making each element a unique and important contributor to modern technology. These specialty metals may face supply constraints in the future, not just because of limited mineral resources, and because of mismatch between demand and available production capacity (Gerling et al 2004). Such a scenario analysis could provide the basis for dynamic assessment of material criticality, as proposed by (Roelich et al 2014; Knoeri et al 2013), by applying the criticality framework developed by (Graedel et al 2012; Nuss et al 2014) in a prospective model
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