Global critical materials markets: An agent-based modeling approach
Authored by Matthew Riddle, Charles M Macal, Guenter Conzelmann, Todd E Combs, Diana Bauer, Fletcher Fields
Date Published: 2015
DOI: 10.1016/j.resourpol.2015.01.002
Sponsors:
United States Department of Energy (DOE)
Platforms:
Repast
Model Documentation:
Other Narrative
Flow charts
Mathematical description
Model Code URLs:
Model code not found
Abstract
As part of efforts to position the United States as a leader in clean
energy technology production, the U. S. Department of Energy (DOE)
issued two Critical Materials Strategy reports, which assessed 16
materials on the basis of their importance to clean energy development
and their supply risk (DOE, 2010, 2011). To understand the implications
for clean energy of disruptions in supplies of critical materials, it is
important to understand supply chain dynamics from mining to final
product production. As a case study of critical material supply chains, we focus on the supply of two rare earth metals, neodymium (Nd) and
dysprosium (Dy), for permanent magnets used in wind turbines, electric
vehicles and other applications. We introduce GCMat, a dynamic
agent-based model that includes interacting agents at five supply chain
stages consisting of mining, metal refining, magnet production, final
product production and demand. Agents throughout the supply chain make
pricing, production and inventory management decisions. Deposit
developers choose which deposits to develop based on market conditions
and detailed data on 57 rare earth deposits. Wind turbine and electric
vehicle producers choose from a set of possible production technologies
that require different amounts of rare earths. We ran the model under a
baseline scenario and four alternative scenarios with different demand
and production technology inputs. Model results from 2010 to 2013 fit
well with historical data. Projections through 2025 show a number of
possible future price, demand, and supply trajectories. For each
scenario, we highlight reasons for turning points under market
conditions, for differences between Nd and Dy markets, and for
differences between scenarios. Because GCMat can model causal dynamics
and provide fine-grain representation of agents and their decisions, it
provides explanations for turning points under market conditions that
are not otherwise available from other modeling approaches. Our baseline
projections show very different behaviors for Nd and Dy prices. Nd
prices continue to drop and remain low even at the end of our simulation
period as new capacity comes online and leads to a market in which
production capacity outpaces demand. Dy price movements, on the other
hand, change directions several times with several key turning points
related to inventory behaviors of particular agents in the supply chain
and asymmetric supply and demand trends. Scenario analyses show the
impact of stronger demand growth for rare earths, and in particular
finds that Nd price impacts are significantly delayed as compared to Dy.
This is explained by the substantial excess production capacity for Nd
in the early simulation years that keeps prices down. Scenarios that
explore the impact of reducing the Dy content of magnets show the
intricate interdependencies of these two markets as price trends for
both rare earths reverse directions - reducing the Dy content of magnets
reduces Dy demand, which drives down Dy prices and translates into lower
magnet prices. This in turn raises the demand for magnets and therefore
the demand for Nd and eventually drives up the Nd price. Published by
Elsevier Ltd.
Tags
Strategies
Rare-earth-elements