As electric vehicles and energy storage systems expand worldwide, demand for cobalt has surged, intensifying concerns over supply security, geopolitical concentration, and environmental and social risks. Traditional assessments of critical minerals often evaluate countries, materials, or trade flows in isolation, overlooking the dense upstream–downstream interdependencies that characterize modern supply chains. Recent disruptions—from export restrictions and trade tensions to pandemic-related shocks—have shown that even localized disturbances can ripple through global production systems. However, existing analytical frameworks struggle to capture how risks propagate across multiple production stages and economies simultaneously. Based on these challenges, it is necessary to conduct in-depth research on cobalt supply chain risks from a systemic, network-based perspective.
In a study (DOI: 10.1016/j.ese.2025.100654) accepted in Environmental Science and Ecotechnology and published online in late 2025, researchers from institutions including the Chinese Academy of Sciences, Peking University, and the University of Southern Denmark analyzed global cobalt flows from 1998 to 2019. Using a multilayer supply chain network and an iterative shock propagation model, the team examined how disruptions spread horizontally across countries and vertically across six life-cycle stages, from mining and refining to manufacturing, use, and recycling. Their findings offer one of the most comprehensive assessments to date of systemic risk in the global cobalt supply chain.
The researchers constructed a global cobalt supply chain network linking 230 countries across six interconnected production stages, combining trade-linked material flow analysis with a dynamic shock-propagation model. This approach allowed them to simulate how supply shortages or demand reductions in one node could trigger cascading failures throughout the system. The results show that shocks propagate through alternating direct and indirect pathways, often traveling across both trade relationships and domestic production chains. While mining disruptions—particularly in highly concentrated upstream regions—are frequent risk sources, the most severe systemic impacts accumulate at refining and manufacturing "bridges", where dense vertical and horizontal connections amplify failures.
The analysis reveals that the resulting "avalanche network" of potential failures is roughly four times denser than the physical trade network itself, indicating extensive hidden interdependencies. Countries such as China and the United States exhibit high systemic fragility, meaning disruptions originating there can trigger widespread collapses. Conversely, several countries with relatively small production volumes but high exposure rates are particularly vulnerable to common random disruptions and lack resilience or effective response. Overall, the study finds that global cobalt supply risks have followed a volatile yet rising trend over the past two decades, driven by increasing concentration and misalignment between supply and demand.
The authors emphasize that the cobalt supply chain displays a "robust-yet-fragile" structure: it can absorb random, small-scale disruptions, yet remains highly vulnerable to targeted shocks at critical nodes. They note that interventions such as national stockpiling or reshoring may reduce risks for individual countries but can unintentionally shift vulnerabilities elsewhere in the system. According to the research team, improving resilience requires coordinated, stage-aware strategies that recognize upstream–downstream coupling rather than isolated national responses. Without such system-level thinking, efforts to secure critical minerals for the energy transition may exacerbate, rather than alleviate, global supply instability.
The findings carry important implications for energy policy, critical mineral governance, and industrial strategy. By revealing where risks originate, accumulate, and propagate, the framework can support early-warning systems for supply disruptions and guide more effective international cooperation. Policymakers can use these insights to design joint stockpiling mechanisms, diversify refining and manufacturing capacity, and evaluate the systemic consequences of trade restrictions or decoupling strategies. Beyond cobalt, the approach can be applied to other critical materials essential for batteries and clean energy technologies. Ultimately, the study suggests that ensuring a stable low-carbon transition depends not only on securing resources, but on managing the complex networks that connect them.
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References
DOI
10.1016/j.ese.2025.100654
Original Source URL
https://doi.org/10.1016/j.ese.2025.100654
Funding information
This work was financially supported by the National Natural Science Foundation of China (72334001, 42530502, and 52270191) and the Humanities and Social Sciences Fund of the Ministry of Education of China (23JZD018).
About Environmental Science and Ecotechnology
Environmental Science and Ecotechnology (ISSN 2666-4984) is an international, peer-reviewed, and open-access journal published by Elsevier. The journal publishes significant views and research across the full spectrum of ecology and environmental sciences, such as climate change, sustainability, biodiversity conservation, environment & health, green catalysis/processing for pollution control, and AI-driven environmental engineering. The latest impact factor of ESE is 14.3, according to the Journal Citation ReportsTM 2024.