China has a quasi-monopoly on the global rare earth supply due to its abundant rare earth reserves, low production costs from cheap labor, heavy investments in rare earth mining industries both domestically and abroad, and leadership in rare earth mining technology. Europe is highly dependent on Chinese rare earth imports for its information technology, clean technology, and defense sectors. The document examines Europe's rare earth dependence on China and analyzes potential implications of a recent WTO ruling against China's rare earth export restrictions, as well as Europe's efforts to diversify its rare earth supply and reduce demand.
1. Brazil is the largest country in Latin America and the fifth largest in the world by area and population. It is dominated by the Amazon River basin.
2. Brazil is one of the fastest developing economies and is the world's largest producer of niobium minerals and the second largest producer of iron ore and bauxite.
3. Between 1999 and 2008, Brazil significantly increased production of iron ore, bauxite, copper, and niobium minerals. It has also become one of the world's fastest growing oil producers following recent offshore discoveries.
This report examines approaches to managing water demand in Europe, focusing on the urban, industrial, and agricultural sectors. It finds that implementing water-saving devices and water metering in households can reduce domestic usage by around 50%. For industry, adopting new technologies and processes that use water more efficiently can achieve significant savings. In agriculture, pricing structures for irrigation water and educating farmers on efficient irrigation practices are important for demand management. The report also evaluates the role of water reuse, integrated water management plans, and the influence of EU policies on sustainable water use across Europe.
This document provides an overview of the nuclear industry in China. It discusses the history and future of nuclear power, China's energy needs and strategic shift towards increasing nuclear power. The regulatory framework for the nuclear industry in China is also examined, including the role of government institutions and challenges for foreign investors. The document aims to analyze China's potential as a future actor in the global nuclear market rather than just a domestic market for foreign suppliers.
This document provides a report on critical raw materials for the EU. It identifies 20 critical raw materials based on an analysis of 54 candidate materials. The critical raw materials have high economic importance for the EU combined with a high risk of supply disruption. Most of the world's supply of raw materials comes from outside the EU, with China being the largest single supplier. The report aims to identify priority actions to ensure secure access to critical raw materials and strengthen EU competitiveness and jobs.
IEA publication, May 2024
Critical minerals, which are essential for a range of clean energy technologies, have risen up the policy agenda in recent years due to increasing demand, volatile price movements, supply chain bottlenecks and geopolitical concerns. The dynamic nature of the market necessitates greater transparency and reliable information to facilitate informed decision-making, as underscored by the request from Group of Seven (G7) ministers for the IEA to produce medium- and long-term outlooks for critical minerals.
The Global Critical Minerals Outlook 2024 follows the IEA’s inaugural review of the market last year. It provides a snapshot of industry developments in 2023 and early 2024 and offers medium- and long-term outlooks for the demand and supply of key energy transition minerals based on the latest technology and policy trends.
The report also assesses key risks to the reliability, sustainability and diversity of critical mineral supply chains and analyses the consequences for policy and industry stakeholders. It will be accompanied by an updated version of the Critical Minerals Data Explorer, an interactive online tool that allows users to explore the latest IEA projections.
Research on the Factors that Influence Carbon Emission in ChinaShuang Zheng
1) The document analyzes factors that influence carbon emissions in China using regression analysis.
2) It finds that GDP, energy efficiency, energy structure, and industry structure have a significant impact on carbon emissions in China.
3) The government should emphasize advanced technology development and optimizing industrial structure to reduce carbon emissions.
The document summarizes key developments in critical minerals markets in 2022 and 2023:
- Demand for critical minerals used in clean energy technologies like batteries and electric vehicles grew rapidly due to record deployment, driving up prices and market size.
- Many critical minerals experienced high price volatility in 2021-2022, though most prices moderated later in 2022, highlighting the importance of stable mineral supplies for affordable energy transitions.
- Countries are implementing new policies to diversify critical mineral supplies and enhance sustainability, shown by nearly 200 policies tracked by the IEA in recent years.
The inaugural Critical Minerals Market Review from the IEA provides the following key findings:
- Demand for critical minerals is growing rapidly driven by record deployment of clean energy technologies like EVs and batteries. This is straining supply chains and contributing to price volatility.
- Countries are implementing new policies to diversify critical mineral supplies and investing heavily in mining projects, but questions remain around the adequacy and sustainability of future supply.
- The battery sector is transforming with new technologies like sodium-ion batteries emerging while recycling is ramping up, but remains concentrated in China for now.
- Automakers and others are increasingly investing directly in critical mineral supply chains to secure materials, but diversified midstream supply
1. Brazil is the largest country in Latin America and the fifth largest in the world by area and population. It is dominated by the Amazon River basin.
2. Brazil is one of the fastest developing economies and is the world's largest producer of niobium minerals and the second largest producer of iron ore and bauxite.
3. Between 1999 and 2008, Brazil significantly increased production of iron ore, bauxite, copper, and niobium minerals. It has also become one of the world's fastest growing oil producers following recent offshore discoveries.
This report examines approaches to managing water demand in Europe, focusing on the urban, industrial, and agricultural sectors. It finds that implementing water-saving devices and water metering in households can reduce domestic usage by around 50%. For industry, adopting new technologies and processes that use water more efficiently can achieve significant savings. In agriculture, pricing structures for irrigation water and educating farmers on efficient irrigation practices are important for demand management. The report also evaluates the role of water reuse, integrated water management plans, and the influence of EU policies on sustainable water use across Europe.
This document provides an overview of the nuclear industry in China. It discusses the history and future of nuclear power, China's energy needs and strategic shift towards increasing nuclear power. The regulatory framework for the nuclear industry in China is also examined, including the role of government institutions and challenges for foreign investors. The document aims to analyze China's potential as a future actor in the global nuclear market rather than just a domestic market for foreign suppliers.
This document provides a report on critical raw materials for the EU. It identifies 20 critical raw materials based on an analysis of 54 candidate materials. The critical raw materials have high economic importance for the EU combined with a high risk of supply disruption. Most of the world's supply of raw materials comes from outside the EU, with China being the largest single supplier. The report aims to identify priority actions to ensure secure access to critical raw materials and strengthen EU competitiveness and jobs.
IEA publication, May 2024
Critical minerals, which are essential for a range of clean energy technologies, have risen up the policy agenda in recent years due to increasing demand, volatile price movements, supply chain bottlenecks and geopolitical concerns. The dynamic nature of the market necessitates greater transparency and reliable information to facilitate informed decision-making, as underscored by the request from Group of Seven (G7) ministers for the IEA to produce medium- and long-term outlooks for critical minerals.
The Global Critical Minerals Outlook 2024 follows the IEA’s inaugural review of the market last year. It provides a snapshot of industry developments in 2023 and early 2024 and offers medium- and long-term outlooks for the demand and supply of key energy transition minerals based on the latest technology and policy trends.
The report also assesses key risks to the reliability, sustainability and diversity of critical mineral supply chains and analyses the consequences for policy and industry stakeholders. It will be accompanied by an updated version of the Critical Minerals Data Explorer, an interactive online tool that allows users to explore the latest IEA projections.
Research on the Factors that Influence Carbon Emission in ChinaShuang Zheng
1) The document analyzes factors that influence carbon emissions in China using regression analysis.
2) It finds that GDP, energy efficiency, energy structure, and industry structure have a significant impact on carbon emissions in China.
3) The government should emphasize advanced technology development and optimizing industrial structure to reduce carbon emissions.
The document summarizes key developments in critical minerals markets in 2022 and 2023:
- Demand for critical minerals used in clean energy technologies like batteries and electric vehicles grew rapidly due to record deployment, driving up prices and market size.
- Many critical minerals experienced high price volatility in 2021-2022, though most prices moderated later in 2022, highlighting the importance of stable mineral supplies for affordable energy transitions.
- Countries are implementing new policies to diversify critical mineral supplies and enhance sustainability, shown by nearly 200 policies tracked by the IEA in recent years.
The inaugural Critical Minerals Market Review from the IEA provides the following key findings:
- Demand for critical minerals is growing rapidly driven by record deployment of clean energy technologies like EVs and batteries. This is straining supply chains and contributing to price volatility.
- Countries are implementing new policies to diversify critical mineral supplies and investing heavily in mining projects, but questions remain around the adequacy and sustainability of future supply.
- The battery sector is transforming with new technologies like sodium-ion batteries emerging while recycling is ramping up, but remains concentrated in China for now.
- Automakers and others are increasingly investing directly in critical mineral supply chains to secure materials, but diversified midstream supply
The inaugural Critical Minerals Market Review from the IEA provides the following key findings:
- Demand for critical minerals is growing rapidly driven by record deployment of clean energy technologies like EVs and batteries. This is straining supply chains and contributing to price volatility.
- Countries are implementing new policies to diversify critical mineral supplies and investing heavily in mining projects, but questions remain around the adequacy and sustainability of future supply.
- The battery sector is transforming with new technologies like sodium-ion batteries emerging while recycling is ramping up, but remains concentrated in China for now.
- Automakers and others are increasingly investing directly in critical mineral supply chains to secure materials, but diversified midstream supply
Our world is changing faster than ever following a rapid succession of crises.
To limit the magnitude of climate change, we need an energy revolution and to
reduce GHGs. Renewable energy and electric mobility require a lot of mineral and
metallic raw materials (whatever the scenario is or will be). The exponential development of information and digital technologies relies on a physical infrastructure:
• High energy consumption (approx 5 of global energy), approx 21 in 2030 according to scenarios 45 for manufacturing, 55 for usages)
• High consumption of materials ( data centres data networks, energy demand, etc
The demand for metals and materials is rapidly increasing (in volumes and diversity) through our lifestyles and world
population.
European industry strongly depends on imports from third countries: 68% of Cobalt comes from DRC, 78% of Lithium from
Chile, 98% of Rare Earth Elements REEs ) from China.
In this context , in 2020 the European Commission published a list of 30 CRMs to remark:
• Their high supply risk due to high import dependency and level of concentration of their production
• Their importance for key sectors in the European economy
• The lack of viable substitutes
• The limitations of recycling
Europe critically needs to secure its supply of CRM:
• Increased recycling and secondary resources
e.g. mine and processing wastes
• Bilateral cooperation with producing countries
• Relocation of extraction and production in European
countries Europe still has significant potential; relocating
production of CRMs requires:
• Large investments and huge amounts of data
• A pan-European approach (geology does not care for
political boundaries!)
• Strong involvement of European geological surveys,
under the coordination of EuroGeoSurveys, to produce
and serve factual scientific information and knowledge on
the European CRM potential
The GSEU EU funded project aims at strengthening the cooperation between national GSOs, under the coordination of EGS. One Work Package is dedicated to mineral resources, the objectives of which are :
• Re-evaluation of European potential in primary onshore and offshore CRMs and mining wastes
• Development of the use of the UNFC classification system in mineral resources databases
• Creation of an International Center of Excellence on Sustainable Resources Management
It will also produce added value knowledge (databases, maps of
metallogenic potential, mineral prospectivity maps, etc.).
Data will be accessed via the EGDI (European Geological Data
Infrastructure) open access web portal :
https://www.europe geology.eu/
American company Applied Materials invested $300 million to establish the world's largest private solar research facility in China. The 400,000 square foot facility will conduct R&D, engineering, product demonstration, testing and training for silicon and thin film solar module manufacturing equipment and processes. It marks a significant private investment in China's growing solar energy market, which is projected to see large increases in photovoltaic installations in the coming years.
This bulletin discusses recent developments in rare earth elements (REE) and other strategic metals. It summarizes that:
1) China unexpectedly kept its 2012 REE export quotas at similar levels to 2011, but introduced a new system that significantly restricts exports of more valuable medium-to-heavy REEs.
2) South Korea's REE imports from China dropped 48.3% in November due to reduced global demand in the suppressed economic environment.
3) Russia and China opened the world's largest lithium battery factory to provide batteries for electric buses and trucks.
Timea Grego ECON 662 Grad Research Paper FinalTimea Grego
This document is a graduate research paper that examines China's foreign direct investment policy and whether it has contributed to China becoming a pollution haven. The paper begins by introducing the topic and outlines its aims to explore the impact of China's FDI policy on the global environment. It then discusses the pollution haven hypothesis and provides examples of studies that have analyzed the relationship between FDI, environmental degradation and China. However, the paper notes that most studies have focused on lax environmental regulations rather than cheap energy resources. The rest of the paper will analyze China's economic reforms and links to trade and FDI, examine whether China is a pollution haven by looking at affected industries and the role of FDI, and consider policy recommendations.
What sustainability means in mining today or what mining means to sustainabil...Mining On Top
The document discusses the role and contributions of mining to sustainability and the global economy. It makes the following key points:
1) Mining contributes around 10% directly and up to 45% indirectly to the global economy through supporting industries and downstream uses of minerals.
2) Mining disturbs less than 1% of the Earth's surface but provides over 45% of global economic activity and is essential for clean water, clean air, and other environmental needs.
3) For mining to be sustainable, it must contribute to human well-being, ecosystem well-being, and economic viability at the local, national and international levels through its operations and post-closure plans.
The 5 Key Challenges in the localisation process of nuclear equipmentArnaud Lefevre-Baril
The document discusses the key challenges in localizing the nuclear equipment supply chain in Turkey. The 5 key challenges are: 1) Rising costs and lack of skills, 2) Lack of local regulation, 3) Absence of a nuclear industrial park, 4) Limited involvement of research institutions and industry, and 5) Lack of a lobbying group. It provides strategies for companies to become sustainable players in the nuclear industry, including developing a strong safety culture, assessing local market and skills, collaborating between research and industry, forming an industry lobbying group, partnering with experienced foreign companies, and establishing nuclear industrial parks.
This document analyzes Chinese and English literature on coal mine accidents in China using data mining algorithms. It finds that 99% of studies are published in Chinese or English, with Chinese authors leading research globally. Chinese studies focus on accident patterns and causes, while English studies examine miners' injuries and typical disaster mechanisms. Research topics in Chinese literature are generally later than in English due to differences in audience, policy, and evaluation systems. After 2018, Chinese studies increasingly focus on AI technology for accident analysis, while English studies' hotspots remain unchanged. Both literatures around 2019 discuss "public opinion", with Chinese studies aiming to guide public opinion for the government and English studies critically examining news authenticity and China's safety strategy.
This document discusses Plateau Energy Metals' lithium and uranium projects in Peru. It summarizes the Falchani lithium project as a clean tech strategic asset, with a large, high-quality resource that is amenable to open pit mining. It also summarizes the Macusani uranium project as a green energy enabler, with strong project economics and potential for growth. Both projects have excellent infrastructure and are located in a geopolitically stable jurisdiction in Peru. The document outlines the company's growth plans for advancing the projects through economic studies and development.
An Investigation On Nuclear Energy Policy In Turkey And Public PerceptionWendy Hager
This document discusses nuclear energy policy and public perception in Turkey. It provides context on Turkey's energy needs and dependence on foreign imports. Nuclear energy is presented as a potential sustainable alternative energy source. The document then reviews the history and role of nuclear power globally and in Turkey. It outlines some of the economic and environmental benefits of nuclear energy compared to fossil fuels. Finally, it evaluates Turkey's public perception of nuclear energy, which has been impacted by past nuclear accidents at Chernobyl and Fukushima. The main points covered are Turkey's energy security issues, nuclear energy as a potential solution, and factors shaping Turkish public opinion on the topic.
This white paper discusses WEEE (waste electrical and electronic equipment) management in Ukraine. It notes that Ukraine generates over 200,000 tons of WEEE annually but lacks an effective management system. Currently most WEEE is dumped or recycled using unsafe methods. The paper recommends that Ukraine establish a regulatory framework for extended producer responsibility and collection/financing schemes for WEEE, based on best practices in the EU. This would help develop a viable recycling industry, ensure environmentally-sound management of WEEE, and recover valuable materials.
Global e waste management market (2011 – 2016)raycarl
The document provides an overview and market analysis of the global e-waste management industry from 2011 to 2016. It finds that the volume of e-waste generated globally is expected to reach 93.5 million tons by 2016, up from 41.5 million tons in 2011, representing a compound annual growth rate of 17.6%. Similarly, the revenue generated from the e-waste management market is projected to grow from $9.15 billion in 2011 to $20.25 billion in 2016 at a CAGR of 17.22%. The report analyzes the market based on material recovery, waste sources, and regional trends, and profiles major industry players.
Day 2- Session 4: Resource Nationalism
How are governments responding to the resource crisis
Objective Capital Global Mining Investment Conference 2010
Stationers' Hall, City of London
28-29 September 2010
Speaker:
Jaakko Kooroshy - The Hague Centre for Strategic Studies
World demand for rare earths is forecast to increase 7.1% annually through 2015 to 180,000 metric tons, driven by growth in batteries, electronics, vehicles, and permanent magnets. Permanent magnets will remain the largest market. Neodymium and dysprosium are expected to have the fastest volume growth for use in heat-resistant magnets. China currently dominates production, but new non-Chinese suppliers are emerging to boost supply and reduce price volatility.
1) The document discusses how the 1957 Soviet launch of Sputnik spurred increased investment in science and technology in the US. It argues that the global energy race today poses a similar challenge for US competitiveness.
2) It notes that countries like China are increasingly investing in energy innovation and cites data showing the US is losing its edge in areas like patents, research publications, and high-tech manufacturing.
3) The document calls for increased US government funding and support for energy research to help capture the economic benefits of innovation and secure continued American leadership in this critical field.
This document provides a structural analysis of the offshore wind innovation systems in the UK, Denmark, the Netherlands, and Germany. It examines the key actors, networks, institutions, and infrastructure components that make up each system. The analysis focuses on identifying the main governmental agencies, knowledge institutions, educational organizations, industrial actors, and support organizations involved in each country's offshore wind sector. It also maps the knowledge networks, lobbying networks, and industrial collaborations that connect actors within each national system. Finally, it describes some of the policies, regulations, expectations, and physical infrastructure supporting offshore wind development across the four countries. The goal of this structural analysis is to understand the composition and interconnections of each innovation system as a foundation for a subsequent functional
The document provides an update on the CoLaBATS project, which aims to develop an innovative chemical process for recycling lithium-ion and nickel-metal hydride batteries. The 11-stage chemical design was completed in December 2014 using Deep Eutectic Solvents and Ionic Liquids. Work will now focus on designing and constructing two pilot plants in the UK and Spain to test the process at a larger scale. The project aims to recover valuable materials like cobalt, lithium, and rare earth elements to contribute to a more circular economy in the EU.
Electricity market reforms in Ukraine. Challenges and opportunitiesUIFuture
The electricity market reforms in Ukraine provide for establishing separate formal and informal market sectors with competition-based pricing, separating distribution companies from suppliers, and introducing incentive-based tariffs for transmission and distribution system operators. The reforms are scheduled to commence on July 1, 2019. Failure to implement the reforms could result in losses of $3.66 billion in annual capital investments, $7.4 billion in annual GDP, and $1.16 billion in annual state budget revenues for Ukraine each year the reforms are delayed.
The document discusses electronic waste (e-waste) and its impacts. It notes that e-waste is growing rapidly worldwide due to the electronics industry. E-waste contains toxic materials that can harm human health and the environment if not properly handled. The document outlines the composition of e-waste, sources of e-waste generation in India and globally, and the environmental and health hazards posed by e-waste, particularly from toxic materials like lead, mercury, and dioxins/furans released during improper recycling and disposal.
The inaugural Critical Minerals Market Review from the IEA provides the following key findings:
- Demand for critical minerals is growing rapidly driven by record deployment of clean energy technologies like EVs and batteries. This is straining supply chains and contributing to price volatility.
- Countries are implementing new policies to diversify critical mineral supplies and investing heavily in mining projects, but questions remain around the adequacy and sustainability of future supply.
- The battery sector is transforming with new technologies like sodium-ion batteries emerging while recycling is ramping up, but remains concentrated in China for now.
- Automakers and others are increasingly investing directly in critical mineral supply chains to secure materials, but diversified midstream supply
Our world is changing faster than ever following a rapid succession of crises.
To limit the magnitude of climate change, we need an energy revolution and to
reduce GHGs. Renewable energy and electric mobility require a lot of mineral and
metallic raw materials (whatever the scenario is or will be). The exponential development of information and digital technologies relies on a physical infrastructure:
• High energy consumption (approx 5 of global energy), approx 21 in 2030 according to scenarios 45 for manufacturing, 55 for usages)
• High consumption of materials ( data centres data networks, energy demand, etc
The demand for metals and materials is rapidly increasing (in volumes and diversity) through our lifestyles and world
population.
European industry strongly depends on imports from third countries: 68% of Cobalt comes from DRC, 78% of Lithium from
Chile, 98% of Rare Earth Elements REEs ) from China.
In this context , in 2020 the European Commission published a list of 30 CRMs to remark:
• Their high supply risk due to high import dependency and level of concentration of their production
• Their importance for key sectors in the European economy
• The lack of viable substitutes
• The limitations of recycling
Europe critically needs to secure its supply of CRM:
• Increased recycling and secondary resources
e.g. mine and processing wastes
• Bilateral cooperation with producing countries
• Relocation of extraction and production in European
countries Europe still has significant potential; relocating
production of CRMs requires:
• Large investments and huge amounts of data
• A pan-European approach (geology does not care for
political boundaries!)
• Strong involvement of European geological surveys,
under the coordination of EuroGeoSurveys, to produce
and serve factual scientific information and knowledge on
the European CRM potential
The GSEU EU funded project aims at strengthening the cooperation between national GSOs, under the coordination of EGS. One Work Package is dedicated to mineral resources, the objectives of which are :
• Re-evaluation of European potential in primary onshore and offshore CRMs and mining wastes
• Development of the use of the UNFC classification system in mineral resources databases
• Creation of an International Center of Excellence on Sustainable Resources Management
It will also produce added value knowledge (databases, maps of
metallogenic potential, mineral prospectivity maps, etc.).
Data will be accessed via the EGDI (European Geological Data
Infrastructure) open access web portal :
https://www.europe geology.eu/
American company Applied Materials invested $300 million to establish the world's largest private solar research facility in China. The 400,000 square foot facility will conduct R&D, engineering, product demonstration, testing and training for silicon and thin film solar module manufacturing equipment and processes. It marks a significant private investment in China's growing solar energy market, which is projected to see large increases in photovoltaic installations in the coming years.
This bulletin discusses recent developments in rare earth elements (REE) and other strategic metals. It summarizes that:
1) China unexpectedly kept its 2012 REE export quotas at similar levels to 2011, but introduced a new system that significantly restricts exports of more valuable medium-to-heavy REEs.
2) South Korea's REE imports from China dropped 48.3% in November due to reduced global demand in the suppressed economic environment.
3) Russia and China opened the world's largest lithium battery factory to provide batteries for electric buses and trucks.
Timea Grego ECON 662 Grad Research Paper FinalTimea Grego
This document is a graduate research paper that examines China's foreign direct investment policy and whether it has contributed to China becoming a pollution haven. The paper begins by introducing the topic and outlines its aims to explore the impact of China's FDI policy on the global environment. It then discusses the pollution haven hypothesis and provides examples of studies that have analyzed the relationship between FDI, environmental degradation and China. However, the paper notes that most studies have focused on lax environmental regulations rather than cheap energy resources. The rest of the paper will analyze China's economic reforms and links to trade and FDI, examine whether China is a pollution haven by looking at affected industries and the role of FDI, and consider policy recommendations.
What sustainability means in mining today or what mining means to sustainabil...Mining On Top
The document discusses the role and contributions of mining to sustainability and the global economy. It makes the following key points:
1) Mining contributes around 10% directly and up to 45% indirectly to the global economy through supporting industries and downstream uses of minerals.
2) Mining disturbs less than 1% of the Earth's surface but provides over 45% of global economic activity and is essential for clean water, clean air, and other environmental needs.
3) For mining to be sustainable, it must contribute to human well-being, ecosystem well-being, and economic viability at the local, national and international levels through its operations and post-closure plans.
The 5 Key Challenges in the localisation process of nuclear equipmentArnaud Lefevre-Baril
The document discusses the key challenges in localizing the nuclear equipment supply chain in Turkey. The 5 key challenges are: 1) Rising costs and lack of skills, 2) Lack of local regulation, 3) Absence of a nuclear industrial park, 4) Limited involvement of research institutions and industry, and 5) Lack of a lobbying group. It provides strategies for companies to become sustainable players in the nuclear industry, including developing a strong safety culture, assessing local market and skills, collaborating between research and industry, forming an industry lobbying group, partnering with experienced foreign companies, and establishing nuclear industrial parks.
This document analyzes Chinese and English literature on coal mine accidents in China using data mining algorithms. It finds that 99% of studies are published in Chinese or English, with Chinese authors leading research globally. Chinese studies focus on accident patterns and causes, while English studies examine miners' injuries and typical disaster mechanisms. Research topics in Chinese literature are generally later than in English due to differences in audience, policy, and evaluation systems. After 2018, Chinese studies increasingly focus on AI technology for accident analysis, while English studies' hotspots remain unchanged. Both literatures around 2019 discuss "public opinion", with Chinese studies aiming to guide public opinion for the government and English studies critically examining news authenticity and China's safety strategy.
This document discusses Plateau Energy Metals' lithium and uranium projects in Peru. It summarizes the Falchani lithium project as a clean tech strategic asset, with a large, high-quality resource that is amenable to open pit mining. It also summarizes the Macusani uranium project as a green energy enabler, with strong project economics and potential for growth. Both projects have excellent infrastructure and are located in a geopolitically stable jurisdiction in Peru. The document outlines the company's growth plans for advancing the projects through economic studies and development.
An Investigation On Nuclear Energy Policy In Turkey And Public PerceptionWendy Hager
This document discusses nuclear energy policy and public perception in Turkey. It provides context on Turkey's energy needs and dependence on foreign imports. Nuclear energy is presented as a potential sustainable alternative energy source. The document then reviews the history and role of nuclear power globally and in Turkey. It outlines some of the economic and environmental benefits of nuclear energy compared to fossil fuels. Finally, it evaluates Turkey's public perception of nuclear energy, which has been impacted by past nuclear accidents at Chernobyl and Fukushima. The main points covered are Turkey's energy security issues, nuclear energy as a potential solution, and factors shaping Turkish public opinion on the topic.
This white paper discusses WEEE (waste electrical and electronic equipment) management in Ukraine. It notes that Ukraine generates over 200,000 tons of WEEE annually but lacks an effective management system. Currently most WEEE is dumped or recycled using unsafe methods. The paper recommends that Ukraine establish a regulatory framework for extended producer responsibility and collection/financing schemes for WEEE, based on best practices in the EU. This would help develop a viable recycling industry, ensure environmentally-sound management of WEEE, and recover valuable materials.
Global e waste management market (2011 – 2016)raycarl
The document provides an overview and market analysis of the global e-waste management industry from 2011 to 2016. It finds that the volume of e-waste generated globally is expected to reach 93.5 million tons by 2016, up from 41.5 million tons in 2011, representing a compound annual growth rate of 17.6%. Similarly, the revenue generated from the e-waste management market is projected to grow from $9.15 billion in 2011 to $20.25 billion in 2016 at a CAGR of 17.22%. The report analyzes the market based on material recovery, waste sources, and regional trends, and profiles major industry players.
Day 2- Session 4: Resource Nationalism
How are governments responding to the resource crisis
Objective Capital Global Mining Investment Conference 2010
Stationers' Hall, City of London
28-29 September 2010
Speaker:
Jaakko Kooroshy - The Hague Centre for Strategic Studies
World demand for rare earths is forecast to increase 7.1% annually through 2015 to 180,000 metric tons, driven by growth in batteries, electronics, vehicles, and permanent magnets. Permanent magnets will remain the largest market. Neodymium and dysprosium are expected to have the fastest volume growth for use in heat-resistant magnets. China currently dominates production, but new non-Chinese suppliers are emerging to boost supply and reduce price volatility.
1) The document discusses how the 1957 Soviet launch of Sputnik spurred increased investment in science and technology in the US. It argues that the global energy race today poses a similar challenge for US competitiveness.
2) It notes that countries like China are increasingly investing in energy innovation and cites data showing the US is losing its edge in areas like patents, research publications, and high-tech manufacturing.
3) The document calls for increased US government funding and support for energy research to help capture the economic benefits of innovation and secure continued American leadership in this critical field.
This document provides a structural analysis of the offshore wind innovation systems in the UK, Denmark, the Netherlands, and Germany. It examines the key actors, networks, institutions, and infrastructure components that make up each system. The analysis focuses on identifying the main governmental agencies, knowledge institutions, educational organizations, industrial actors, and support organizations involved in each country's offshore wind sector. It also maps the knowledge networks, lobbying networks, and industrial collaborations that connect actors within each national system. Finally, it describes some of the policies, regulations, expectations, and physical infrastructure supporting offshore wind development across the four countries. The goal of this structural analysis is to understand the composition and interconnections of each innovation system as a foundation for a subsequent functional
The document provides an update on the CoLaBATS project, which aims to develop an innovative chemical process for recycling lithium-ion and nickel-metal hydride batteries. The 11-stage chemical design was completed in December 2014 using Deep Eutectic Solvents and Ionic Liquids. Work will now focus on designing and constructing two pilot plants in the UK and Spain to test the process at a larger scale. The project aims to recover valuable materials like cobalt, lithium, and rare earth elements to contribute to a more circular economy in the EU.
Electricity market reforms in Ukraine. Challenges and opportunitiesUIFuture
The electricity market reforms in Ukraine provide for establishing separate formal and informal market sectors with competition-based pricing, separating distribution companies from suppliers, and introducing incentive-based tariffs for transmission and distribution system operators. The reforms are scheduled to commence on July 1, 2019. Failure to implement the reforms could result in losses of $3.66 billion in annual capital investments, $7.4 billion in annual GDP, and $1.16 billion in annual state budget revenues for Ukraine each year the reforms are delayed.
The document discusses electronic waste (e-waste) and its impacts. It notes that e-waste is growing rapidly worldwide due to the electronics industry. E-waste contains toxic materials that can harm human health and the environment if not properly handled. The document outlines the composition of e-waste, sources of e-waste generation in India and globally, and the environmental and health hazards posed by e-waste, particularly from toxic materials like lead, mercury, and dioxins/furans released during improper recycling and disposal.
1. EUROPE’S RARE EARTH
DEPENDENCE ON CHINA:
FUTURE PERSPECTIVES
JULIA EBNER
December 2014
EIAS BRIEFING PAPER 2014 │ 07
EUROPEAN INSTITUTE
FOR
ASIAN STUDIES
2. Julia Ebner
European Institute for Asian Studies 1
Europe’s Rare Earth Dependence on China
Future Perspectives
By Julia Ebner1
Abstract
In view of the EU 2020 energy targets and the indispensability of rare earths for the
ICT and clean technology sector, European demand for rare earths will likely continue
to increase progressively in the years to come. Whilst Europe has made considerable
efforts to decrease its dependence on China’s rare earths by investing in domestic
primary production and R&D of substitutes and recycling, it is today still fully
dependent on external supply, mostly from China. Aiming at providing an analysis of
the status quo and recent trends of Europe’s dependence on China’s rare earths, the
briefing paper assesses developments on both the supply and demand side of the
Sino-European rare earth market. After explaining China’s quasi-monopoly, Europe’s
ICT and clean technology dependence on rare earths and the evolution of Chinese rare
earth policies, it examines potential implications of the March 2014 WTO decision for
China’s rare earths supply equation. The paper then analyses Europe’s efforts to
increase and diversify its primary supply and to decrease its demand for rare earths. It
makes use of interviews with European and Chinese rare earth policy and industry
experts and concludes by sketching future scenarios for the Sino-European rare earths
trade and Europe’s supply security.
This paper expresses the views of the author and not the views of the European Institute for Asian Studies.
1
Julia Ebner is a Junior Researcher at the European Institute for Asian Studies, e-mail: julia.ebner@eias.org
3. Europe’s Rare Earth Dependence on China: Future Perspectives
2 European Institute for Asian Studies
Table of Contents
I. Introduction............................................................................................................. 3
II. China’s Quasi-Monopoly............................................................................................. 5
III. Europe’s Rare Earth Dependence ................................................................................ 8
IV. The Evolution of Chinese Rare Earth Policies .............................................................. 10
V. Implications of the March 2014 WTO Ruling for China’s Supply Equation........................ 11
VI. Europe’s Role in International Rare Earth Market Dynamics.......................................... 16
VII. Future Predictions and Scenario Analysis ................................................................... 21
VIII. Conclusions and Recommendations........................................................................... 24
IX. Bibliography........................................................................................................... 26
X. List of Figures ........................................................................................................ 29
XI. List of Interviewees................................................................................................. 30
XII. Acknowledgements ................................................................................................. 30
4. Julia Ebner
European Institute for Asian Studies 3
List of Abbreviations
DOE: Department of Energy (US)
EC: European Commission
ERECON: European Rare Earths Competency Network
ICT: Information and communication technology
LED: Light-emitting diode
METI: Ministry of Economy, Trade and Industry (Japan)
MIIT: Ministry of Industry and Information Technology (Japan)
MOFCOM: Ministry of Commerce (China)
NdFeB: Neodymium magnets
NEDO: New Energy and Industrial Technology Development Organization (Japan)
NFC: Non-Ferrous Metal Industry’s Foreign Engineering and Construction Co. Ltd.
R&D: Research and Development
WTO: World Trade Organization
5. Europe’s Rare Earth Dependence on China: Future Perspectives
4 European Institute for Asian Studies
I. Introduction
“The Middle East has oil, China has rare earths,” Deng Xiaoping said in 1992, recognising
the strategic importance of rare earths over two decades ago.2
Supplying more than 85 per
cent of the world’s rare earths3
, China today has a quasi-monopoly on the 17 rare earth
elements 4
at the bottom of the periodic table. Even though American Molycorp and
Australian Lynas recently ramped up their mining and processing capacities, causing a
reduction of China’s share in global output from 95 per cent in 2010 to an estimated 75 per
cent in 2015, China’s monopoly for heavy rare earth elements remains unchallenged.5
Europe’s information and communication technology (ICT), clean technology and defense
sectors are therefore to a large extent dependent on Chinese rare earths, which are
indispensable for the production of such products as smartphones, computers, solar panels,
lasers, and electric car batteries.
When China’s Rare Earth Office was transferred to the Ministry of Industry and Information
Technology (MIIT) in 20086
, it started to impose restrictions on the export of rare earth
metals7
, including export quotas and tariffs. In particular, China started to curb its rare
earths exports to Europe, the US and Japan.8
This caused great concern in Europe, as a rare
earth supply shortage would not only negatively impact the EU’s innovativeness and
competitiveness in the high tech industry but also impede progress in the emerging
alternative energy sector (e.g. energy-saving lighting, electric cars, fuel cells, photovoltaics
or windmills).9
Although Beijing initially stated that the reduction was a measure to protect the
environment and its national resources, the suspension of exports to Japan after the
Senkaku/Diaoyu boat collision incident in 2010 was “widely perceived as China using its
control over crucial minerals as a tool of its foreign policy.”10
In reaction to this, the US,
Japan and the EU jointly filed a case against China and demanded a dispute settlement by
the WTO. In March 2014, the WTO investigation reached the conclusion that China’s rare
earth policies constituted a violation of international trade law, saying that “China’s export
quotas were designed to achieve industrial policy goals” 11
rather than to mitigate
environmental pollution. After China appealed these panel reports in late April the dispute
settlement body adopted the appellate body reports with recommendations to bring
measures into conformity on August 29, 2014.
2
Brennan, Eliot. (2012). Rare earths – the next oil. Asian Times. Retrieved from
http://www.atimes.com/atimes/China_Business/NC16Cb01.html.
3
Gravgaard, Anna. (2013). Greenland’s Rare Earths Gold Rush. Foreign Affairs. The Council of Foreign Relations.
Retrieved from http://www.foreignaffairs.com/features/letters-from/greenlands-rare-earths-gold-rush.
4
The 17 rare earth elements are lanthanum, cerium, praseodymium, neodymium, promethium, samarium,
europium, gadolinium, terbium, dysprosium, holmium, erbium, thulium, ytterbium, lutetium, yttrium and scandium
5
Information received in the interview with Dr. Günter Tiess and Dr. Horst Hejny
6
Tse, Pui-Kwan. (2011). China’s Rare Earth Industry. US Geological Survey, p.5
7
Those restriction where not only imposed on rare earths but also on tungsten and molybdenum
8
Jiji.(2014, March 24). Japan, US, EU win rare earths dispute over China, The Japan Times. Retrieved from
http://www.japantimes.co.jp/news/2014/03/26/business/japan-u-s-eu-win-rare-earth-dispute-with-
china/#.U0zgglcgRZg.
9
Cf. Massari, Stefania and Ruberti, Marcello. (2013). Rare earth elements as critical raw materials: Focus on
international markets and future strategies. Resources Policy 38, 36-43.
10
Farooki, Masuma. China and mineral demand – more opportunities than risk?. Polinares Working Paper. n.75.
Retrieved from http://www.polinares.eu/docs/d5-1/polinares_wp5_chapter5_4.pdf.
11
WTO. (2014). China – Measures Related to the Exportation of Rare Earths, Tungsten and Molybdenum. Retrieved
from http://www.wto.org/english/tratop_e/dispu_e/cases_e/ds431_e.htm.
6. Julia Ebner
European Institute for Asian Studies 5
In recent years, much research has been conducted on the controversy of China’s rare earth
export restrictions. The case has been looked at from various angles: political, macro-
economic, legal and technological analyses have demonstrated the complexity and
multifacetedness of the topic. While most of the existing literature has provided descriptions
or analyses of certain aspects of China’s rare earth monopoly, this paper attempts to draw
conclusions from rare earth trends and power shifts on the demand and the supply side of
the rare earths market as well as the interplay between domestic policies and international
market trends. The paper examines the Chinese rare earth controversy in light of the recent
WTO ruling, thus adopting a post-August 2014 perspective, and provides future scenarios
for EU-China rare earth trade. More specifically, the paper integrates the market and supply
equation implications of the WTO decision and analyses developments and emerging
alternatives in the European rare earth demand.
First of all, the paper explains the status quo of Sino-European rare earth relations, by
providing reasons for China’s quasi-monopoly and Europe’s dependence on Chinese rare
earths as well as a brief overview on the evolution of China’s rare earth policies. After
providing this status quo analysis, the paper concentrates on future perspectives and
expected shifts in the rare earth market. On the one hand, the briefing paper attempts to
analyse China’s expected reaction to the recent WTO ruling, in other words, changes on the
supply side of the market. On the other hand, it tries to examine future trends for Europe’s
role in the international rare earth competition dynamics, that is to say changes on the
demand side. In the end, a brief future scenario analysis and a conclusion with the main
findings are provided.
The paper makes use of recently published specialist books, academic journal articles,
newspaper articles, reports issued by governmental and non-governmental institutions
mainly in Europe and China, conference protocols as well as available statistics, graphics
and empirical studies on the topic. Apart from the literature research, the paper draws
conclusions from interviews with experts in the field of rare earths and EU-China minerals
trade. In order to provide a non-biased analysis, interviews have been conducted with
representatives from both the Chinese and the European side as well as from both the
private and the public sector. Concretely, experts from academic institutions, think tanks,
Chinese and European governmental institutions, private companies and independent
researchers and trend analysts have been consulted. The full list of interviewees can be
found in the appendix.
II. China’s Quasi-Monopoly
Today, China is the world’s biggest producer and exporter of commercial quantities of rare
earth materials, accounting for over 85 per cent of the global rare earth output.12
The Inner
Mongolia Autonomous Region is well-known as China’s leading rare earth producer,
supplying between 50 and 60 per cent of China’s total rare earth concentrate output since
the early 2000s. However, other provinces such as Fujian, Guangdong, Jiangxi, and Sichuan
have also become important producers of rare earth materials in China.13
In fact, rare earths are not as rare as their name suggests. Some of them are even more
abundant than other minerals such as copper, lead, gold and platinum. However, their
12
Gravgaard, Anna. (2013). Greenland’s Rare Earths Gold Rush. Foreign Affairs. The Council of Foreign Relations.
Retrieved from http://www.foreignaffairs.com/features/letters-from/greenlands-rare-earths-gold-rush.
13
Tse, Pui-Kwan. (2011). China’s Rare Earth Industry. US Geological Survey. Open File Report 2011-1042, p.1.
7. Europe’s Rare Earth Dependence on China: Future Perspectives
6 European Institute for Asian Studies
extraction and processing requires high initial investments and advanced technology and
produces toxic waste. Another problem is that rare earth elements are frequently not
concentrated enough for their extraction to be economically viable.14
Currently there are
only two major producers of rare earths that can be found outside of China: the US-based
company Molycorp and Australia’s Lynas. Thanks to their recent production revival at the
Californian Mountain Pass mine and Australia’s Mount Weld, China’s share of rare earth
output has fallen from more than 95 per cent in 2010 to 85 per cent in 2013.15
The first rare earth deposits were discovered in 1787 in Sweden. It was almost 100 years
later that rare earths were first used in commercial products. The early 20th
century saw the
dawn of large-scale rare earth production, with Brazil and India being the first countries to
produce and export rare earths, followed by Australia and Malaysia who commenced their
exports in the 1940s. The US started to extract rare earths for export, principally from the
Mountain Pass Mine in California, in the 1960s and became the world’s leading exporter by
the 1980s. China did not enter the stage and penetrate the international rare earth market
until the early 1980s. However, it quickly rose to become a major low-cost rare earth
producer and overtook the US as the world’s biggest exporter in 1988. This transition in the
global supply chain of rare earths has entailed some dramatic changes in market terms. In
the 1990s, the US, the EU, Japan and other rare earth producing countries decided that it
was cheaper, hence more beneficial, and at some point even inevitable, to discontinue past
production chains and instead source rare earths from the low-cost producer China. Ever
since gaining momentum, China has increasingly dominated the global rare earth arena and
today enjoys an almost monopolistic status.16
China’s quasi-monopoly in the extraction, production and export of rare earths does not
come as a surprise, considering some major competitive advantages the country benefits
from in regards to its rare earth industry:
1. Home to over 50 per cent of the global rare earth reserves17
, China is the world’s richest
country in rare earth resources. Since China’s first discoveries of rare earth elements in
Bayan Obo in 1927, rare earths have been found in 21 of the 34 Chinese Provinces and
Autonomous Regions. Besides China’s abundant rare earth resources, large-scale
deposits can only be found in a very limited number of countries, including the US,
Russia, Brazil and the Democratic Republic of Congo. Although these countries have
increased their rare earth production in recent years, they still cannot challenge China’s
quasi-monopoly.18
2. China’s fast rise to a leading rare earth producer can furthermore be explained by the
country’s cheap labour advantage. Its access to low-cost human resources was crucial
for its success as a cheap producer of rare earth materials and enabled the country to
rapidly overtake the US production capacities and to establish a virtual global monopoly
based on its cost advantage.19
Despite the limited availability of price information due to
rare earth contracts being negotiated between operators and not traded on stock or
14
Humphries, Marc. (2013). Rare Earth Elements: The Global Supply Chain. Congressional Research Service. CRS
Report for Congress. p.2.
15
Gravgaard, Anna. (2013). Greenland’s Rare Earths Gold Rush. Foreign Affairs. The Council of Foreign Relations.
Retrieved from http://www.foreignaffairs.com/features/letters-from/greenlands-rare-earths-gold-rush.
16
Blakely, C., Cooter, J. et al. (n.d). Rare Earth Metals & China. Gerald R. Ford School of Public Policy, p.5.
17
Statista. (2013). Rare earth reserves worldwide as of 2013, by country (in 1,000 metric tons of REO). Retrieved
from http://www.statista.com/statistics/277268/rare-earth-reserves-by-country/.
18
Blakely, C., Cooter, J. et al. (n.d). Rare Earth Metals & China. Gerald R. Ford School of Public Policy, p.6.
19
Blakely, C., Cooter, J. et al. (n.d). Rare Earth Metals & China. Gerald R. Ford School of Public Policy, p.5.
8. Julia Ebner
European Institute for Asian Studies 7
future markets, there is strong evidence of a significant price discrepancy between
Chinese rare earth prices and prices of producers outside of China.20
3. Moreover, China’s tremendous economic growth, almost permanently in double digits for
more than three decades, has equipped the country with sufficient funds not only to
invest heavily in domestic mineral production but also to pour vast sums of capital into
other countries’ mining industries by acquiring mining licenses and establishing
extraction and processing facilities abroad.21
4. Additionally, the country’s continuous efforts to expand its geological and technological
knowledge in the field of mining through research and development (R&D) and
knowledge transfer have transformed China into a global leader for cutting edge
technology and expertise in the mining sector. Since the US and Europe have been
reluctant to invest equally high sums in their geological research and their mining
technologies, China now dominates all four steps in the rare earth supply chain:
extraction, processing, purification and production.22
5. China’s lenient environmental laws have also played an important role in the country’s
conquest of the international mining sector.23
In reaction to the toxic wastewater leaks
of the 1990s and similar mining-related ecological scandals, industrialised countries
imposed stricter environmental standards which have considerably impeded progress in
the American and European mining sectors. While, for example, US mining companies
such as Molycorp had to temporarily restrict or even stop their mining activities in order
to fulfil new environmental requirements, China could further develop its supremacy in
the international rare earth industry.24
6. China has benefited from a centrally planned, consolidated long-term minerals policy
which is based on an interactive stakeholder consensus and integrates rare earth
policies into the general resource management strategy. Contrary to China, the EU did
not consider rare earths as strategically important resources until 2007, when it started
to pursue a more comprehensive raw materials policy. Although first steps towards
better defined European minerals policy have been undertaken in the course of the EU’s
Raw Materials Initiative of 2008, Europe is far from reaching a consolidated mineral
resources policy or a concrete rare earth supply security strategy. Hence, China’s
farsightedness has seemed to pay off, as Europe and other rare-earth dependent
countries are struggling to achieve what China has long had in place.25
7. Another significant competitive advantage of Chinese rare earth producing companies
arises from the strong governmental support they enjoy. Most Chinese mining
companies operate as SOEs and are thus legally backed and financially supported by the
government. 26
This also means that Chinese rare earth producers can quickly react to
20
Hayes-Labruto, L., Schillebeeckx, S. et al. (n.d.) Contrasting Perspectives on China’s Rare Earth Policies:
Refraiming the Debate through a Stakeholder Lens. Retrieved from
http://www.academia.edu/2779606/Contrasting_Perspectives_on_Chinas_Rare_Earths_Policies_Reframing_the_De
bate_through_a_Stakeholder_Lens.
21
Information received in the interview with Dr. Günter Tiess and Dr. Horst Hejny
22
Xiaojing, Liu. (2014). China to Form Two Rare Earth Metals Conglomerates. Caixin Online. Retrieved from
http://english.caixin.com/2014-08-07/100714129.html.
23
Blakely, C., Cooter, J. et al. (n.d). Rare Earth Metals & China. Gerald R. Ford School of Public Policy, p.5.
24
Information received in the interview with Dr. Günter Tiess and Dr. Horst Hejny
25
Ibid.
26
Cf. Davis, Bob. (2014). China’s State-Owned Sector Gets a Boost. The Wall Street Journal. Retrieved from
http://online.wsj.com/articles/SB10001424052702303636404579396933232035544.
9. Europe’s Rare Earth Dependence on China: Future Perspectives
8 European Institute for Asian Studies
market changes such as spontaneous drops in the rare earth demand or unexpected
competition on the supply side. As government subventions allow for substantial price
reductions whenever needed, China seems to have almost complete control over the
international rare earth market.
8. One last key advantage is China’s large-scale production of iron ore. As rare earths are a
by-product of iron ore mining, an industry in which China would invest in any case, rare
earth investments appear to be less costly and less risky for Chinese mining companies
than for European ones.27
To conclude, China’s notable competitive advantages in the rare earth industry which have
their source mainly in the favourable conditions underlying the country’s mining sector,
have contributed to the creation of a Chinese quasi-monopoly which can realistically not be
challenged in the short-term. China’s quasi-monopolistic presence in the rare earth market
has equipped the country not only with enormous market power but has also been
translated in considerable diplomatic and political power. This was particularly well reflected
in the case of rare earth export restrictions targeting Japan after the Senkaku/Diaoyu
conflict escalated with the boat collision incident in September 2010. China was blamed by
the US, Europe and Japan for instrumentalising its control over the world rare earth
resources and using it as leverage for the country’s political purposes, especially in its
dealings with Japan.28
III. Europe’s Rare Earth Dependence
At the present moment, Europe has no access to domestic rare earth resources. Despite
the existence of potentially mineable rare earth deposits in numerous European countries,
such as the UK, Germany, Sweden, Finland, Greece and Greenland, geological constraints,
economic unprofitability and strict environmental standards have hitherto hampered
extraction. Soaring rare earth prices following China’s export restrictions in 2011 and
subsequently rising concerns about Europe’s rare earth supply security have, however,
resulted in intensified public as well as private investments in the exploration and
assessment of Europe’s rare earth deposits. Until now, exploration efforts are considered
to be in an advanced stage only in Greenland (Kvanefjeld) and Sweden (Nora Kärr).29
Besides the unexploited European mining potential, there are also bottlenecks linked to
the processing and the separation of rare earths, a key step in the rare earth supply chain.
Sophisticated European separation facilities are currently only found in France and Estonia.
Europe is therefore to a large extent dependent on the supply of concentrates from China
and other countries, such as the US and Russia.30
In 2010, an Ad-Hoc Working Group on Defining Critical Raw Materials of the European
Commission published the first analysis for raw materials, defining the rare earth elements
as critical resources with a high supply risk. As shown in the following graphic, the working
group divided the rare earth elements into two categories: light and heavy rare earth
elements. The matrix below reveals a rather low economic importance of both the light
and the heavy rare earth elements, as compared to other critical raw materials. Yet, it also
27
Information received in the interview with Prof. Dr. Arnold Tukker
28
Blakely, C., Cooter, J. et al. (n.d). Rare Earth Metals & China. Gerald R. Ford School of Public Policy, p.5.
29
ERECON. (2014). Working Group I: Opportunities and road blocks for primary supply of rare earths in Europe.
Retrieved from http://ec.europa.eu/enterprise/policies/raw-materials/erecon/expertise/working-group-1_en.htm.
30
Ibid.
10. Julia Ebner
European Institute for Asian Studies 9
illustrates the relatively high supply risk of light rare earth elements and the eminently
risky nature of the heavy rare earth elements supply.31
Figure 1: Raw Materials Criticality Analysis 2010, European Commission
With the EU’s 2020 goals on lowering its use of fossil fuels, its growing demand for hi-tech
devices and green technology products such as electric cars, solar panels and windmills and
its ambitions to decrease its dependence on Russia’s gas in the light of the Ukraine crisis,
Europe is expected to experience climbing demand levels for rare earth materials.32
In
particular, the demand for neodymium, dysprosium and praseodymium is predicted to rise
in the close future.33
Since, until today, most rare earth products have no or few effective
substitutes and their recycling rate generally remains low34
, a shortage in rare earths could
have devastating effects for the European economy. Albeit progress made in the
development of alternatives to rare earths, the concentrates are currently still indispensable
for the European ICT and clean technology sector. Most likely, clean technology would be
the first sector to be adversely affected by a potential rare earth bottleneck in the EU, owing
to the fact that the demand is hardly predictable and that the quantities required today are
incommensurate with those consumed some years ago. For example, this would apply to
the rare earth element neodymium-iron-boron which is needed for the production of
sintered permanent magnets used in wind turbines.35
31
European Commission. (2014). Defining ‘critical’ raw materials. Retrieved from
http://ec.europa.eu/enterprise/policies/raw-materials/critical/index_en.htm.
32
ERECON. (2014). Rare earth in Europe. Retrieved from http://ec.europa.eu/enterprise/policies/raw-
materials/erecon/index_en.htm.
33
Wells, Steve. (2013). Emerging Alternatives to Rare Earth Elements. Futurium. European Commission. Retrieved
from https://ec.europa.eu/digital-agenda/futurium/en/node/1637.
34
Massari, Stefania and Ruberti, Marcello. (2013). Rare earth elements as critical raw materials: Focus on
international markets and future strategies. Resources Policy 38, 36-43.
35
Information received in the interview with Dr. Günter Tiess and Dr. Horst Hejny
11. Europe’s Rare Earth Dependence on China: Future Perspectives
10 European Institute for Asian Studies
IV. The Evolution of Chinese Rare Earth Policies
Upon the introduction of the Mineral Resources Law in the 1980s, the Chinese government
adopted a planned exploitation policy for strategically important minerals.36
In 1990, the
government further issued a declaration in which it defined rare earths as a protected and
strategic mineral. Since then, foreign investors were no longer allowed to engage in any
mining activity, unless they formed a joint venture with a Chinese company. Furthermore,
all rare earth mining and smelting projects required permission from the State Development
and Planning Commission (SDPC).37
Later, in the 1990s and 2000s, the Chinese government made efforts to limit the country’s
rare earth production and exports in order to avoid high pollution levels caused by excessive
mining. Since the economic development of many regions depended to a large extent on
the rare earth sector, multiple local governments did not adhere to the new national
guidelines, which led to output levels clearly exceeding the production quotas.38
Moreover, a
substantial percentage of the output was generated by investors extracting rare earths
without proper mining licenses, hence often using old technical equipment which did not
meet the industry standards and caused significant harm to the environment. As a
consequence, Beijing has been tightening its measures to enforce the implementation of the
national rare earth policies during the past decade, in particular by shutting down illegal
mines in Guangdong, Jiangxi, and Sichuan.39
In recent years, China has further increased its control over rare earth mining and
production volumes, by implementing a system of mining rights allocation plans. Since 2007,
rare earths production is subject to mandatory planning and since the National Plan for
Mineral Resources for the period of 2008-2015 was issued in 2008, the state exercises
comprehensive regulation and control, restricts the rare earths exploitation and decides on
their utilisation.40
Under the label of environmental protection and resource conservation,
China furthermore restricted rare earth trade in 2010 by imposing export quotas, duties and
limitations on trading rights of enterprises with export permissions.41
In response to these restrictions, the US lodged a complaint at the WTO in March 2012,
claiming that China’s export policies were inconsistent with the WTO rules and China’s
protocol of accession. Japan and the EU, both similarly concerned about China’s export
constraints, joined forces with the US only a few days later.42
36
The State Council Information Office of the People’s Republic of China. (2012). III. Effectively Protecting and
Rationally Utilizing Rare Earth Resources. Retrieved from
http://www.scio.gov.cn/zxbd/nd/2012/Document/1175401/1175401_4.htm.
37
Tse, Pui-Kwan. (2011). China’s Rare Earth Industry. US Geological Survey. Open File Report 2011-1042, p.2.
38
China State Council. (2006). Instruction for mineral resource development: Beijing, China, China State Council
Circular 108. December 31, 5 p. (In Chinese).
39
Tse, Pui-Kwan. (2011). China’s Rare Earth Industry. US Geological Survey. Open File Report 2011-1042, p.2.
40
The State Council Information Office of the People’s Republic of China. (2012). III. Effectively Protecting and
Rationally Utilizing Rare Earth Resources. Retrieved from
http://www.scio.gov.cn/zxbd/nd/2012/Document/1175401/1175401_4.htm.
41
WTO. (2014). China – Measures Related to the Exportation of Rare Earths, Tungsten and Molybdenum. Retrieved
from http://www.wto.org/english/tratop_e/dispu_e/cases_e/ds431_e.htm.
42
Ibid.
12. Julia Ebner
European Institute for Asian Studies 11
V. Implications of the March 2014 WTO Ruling for China’s Supply Equation
In late March 2014 the WTO Dispute Settlement Body issued a panel report on the China
rare earths case, concluding that China’s export restriction measures indeed constituted a
violation of China’s WTO obligations.43
While China did not make a plea against any of the
final conclusions of the WTO panel, it appealed some intermediate judgments in order to
“obtain clarification of the systemic relationship between specific provisions in China’s
Accession Protocol, and other WTO agreements, and of the rights of WTO Members to
protect and conserve their exhaustible natural resources.” 44 According to the Appellate Body
Report issued on August 7 2014, most of China’s appeals including interpretations and
allegations that the Panel failed to comply with its duty were, however, declined.45
In reaction to the panel report, China’s Principal of the Department of Treaty and Law of the
Ministry of Commerce (MOFCOM) gave a speech, saying that he regretted the WTO decision
on China’s export restrictions. He furthermore announced that China will respect the WTO
rules and act accordingly.46
Indeed, China has a good record of implementing WTO rulings
and has always respected WTO decisions, as Mr. Xie Wei, a MOFCOM representative to the
EU, stressed in an interview.47
Mr. Xie Wei, however, also pointed out that China will need
time to implement the new WTO ruling and that China, Japan, the US and the EU will agree
on a reasonable timeline, depending on how complicated the implementation is.48
The decision of the WTO Dispute Settlement Body has put China under severe pressure. It
faces a multitude of conflicting interests, the most important ones being: fulfilling its WTO
obligations, satisfying its domestic demand for rare earths, upholding its competitive edge
and meeting its own sustainability and environmental protection targets.49
Keeping the
balance between those interests will not be an easy undertaking, in particular in view of the
growing demand for rare earth products both on a domestic and on an international level.
The consequences of the WTO decision for China on a macro-economic, micro-economic and
environmental level are hardly predictable due to the highly complex nature of China’s
supply equation. It seems that neither Chinese rare earth supply decisions nor the impacts
of the recent WTO ruling can be narrowed down to only one factor, be it industrial policy
strategies, market domination calculus or environmental impacts, all of which – considered
in isolation from the other factors – risk to oversimplify China’s highly complex rare earths
dilemma.
43
WTO. (2014). China – Measures Related to the Exportation of Rare Earths, Tungsten and Molybdenum. Retrieved
from http://www.wto.org/english/tratop_e/dispu_e/cases_e/ds431_e.htm.
44
Ibid.
45
Ibid.
46
MOFCOM. (2014). Principal of Department of Treaty and Law of MOFCOM Gives a Speech on WTO’s Panel Report
on the Case of the US, EU and Japan’s Action Against China’s Export Management Measures of Relevant Rare
Earth, Tungsten and Molybdenum Products. Retrieved from
http://english.mofcom.gov.cn/article/newsrelease/policyreleasing/201404/20140400538135.shtml.
47
Information received in the interview with Mr Xie Wei
48
Ibid.
49
Ibid.
13. Europe’s Rare Earth Dependence on China: Future Perspectives
12 European Institute for Asian Studies
a.) Implications for China’s domestic supply
China’s rare earths resource depletion is regulated in a comprehensive three level quota
system, covering the country’s mining quota (set up in 2006), the country’s production
quota (set up in 2007) and the country’s export quota (set up in 2010).50
In order to allow
for a coherent rare earth policy that makes sense economically, politically and ecologically,
China uses these three quotas simultaneously. This means that, if one quota is changed,
China needs to readapt the other two quotas. In consequence, the WTO decision does not
only impact China’s export quota but indirectly also affects China’s mining and production
quotas. If the export quota is lifted, while the mining and production quotas remain in place,
this could result in a domestic shortage. As rare earths are also needed for the Chinese ICT
industry, China’s production is likely to be impacted, in case the mining and production
quotas are not increased adequately in order to meet domestic demand.51
Figure 2 illustrates global rare earths supply and demand for the year 2013. As
demonstrated in the graphic, global supply is notably below global demand, indicating harsh
competition resulting from the zero-sum nature of the current rare earths game. The chart
also shows the proportion of China’s rare earth production in comparison to production by
the rest of the world. As suggested in previous chapters, rare earth production outside of
China only constitutes a very small part of total rare earth production, rendering most
countries dependent on Chinese rare earth supply. The graphic furthermore displays China’s
export quota of 30,999 metric tons of rare earth elements in 2013, as announced in two
semi-annual statements by MOFCOM. The chart shows that with the export quotas in place,
Chinese exports (30,999 metric tons) plus production in the rest of the world (11,740
metric tons) are slightly under the demand level for rare earths outside of China (44,640
metric tons). A lifting of the export quota seems to solve this problem at the cost of Chinese
demand; it would ceteris paribus be likely to threaten China’s own supply security. Already,
Chinese demand cannot be met anymore due to the rapidly growing domestic consumption
levels; in the long term constantly rising domestic and global demand for rare earth
products would further exacerbate this problem.
50
Information received in the interview with Mr Xie Wei
51
Ibid.
14. Julia Ebner
European Institute for Asian Studies 13
Figure 2: Rare Earth Supply and Demand 2013, author’s compilation of data from USGS Mineral
Commodity Survey 2013, MOFCOM, Arafura Resources Limited and Avalon Rare Earth Metals Inc.
b.) Implications for China’s industrial production and FDI
A critical part of China’s rare earth strategy and thus a key reason for the country’s export
restrictions during the past few years has been to avoid wasting the country’s strategic
resources by selling them off cheaply as primary goods to foreign countries and thereby
running the risk of becoming a victim of what is often referred to as the “resource curse”.
Instead, it seems that China’s goal has been to replace its exports of unprocessed rare
earth oxide concentrates by exports of processed, high-value rare earth products. By
restricting the export of rare earth oxide concentrates, China could make sure that major
parts of the processing and value creation would take place on Chinese territory. The rare
earth sector thus experienced a notable transition from purely primary sector activities of
extraction to secondary sector activities of processing and manufacturing. This proved to be
an effective strategy not only to upgrade the industry and to accelerate technological
progress52
, but also to force companies operating in rare-earth-related industries to move to
China, so as to gain access to “steady and affordable supply of rare earths”. 53
For example,
several German companies migrated to China when their supply chains were interrupted as
a result of China’s rare earth restrictions in 2010, according to Günter Tiess and Horst
Hejny, experts on the European mining industry.54
The Chinese rare earth strategy thus
boosted FDI in China’s mining sector and allowed for increased knowledge transfers from
foreign countries, in particular due to China’s strict joint-venture requirements.55
If now
export quotas are lifted as a result of the WTO ruling of March 2014, this could potentially
result in decreased demand for Chinese processed rare earth products and an outflow of
52
Conclusions drawn from the interview with Mr Duncan Freeman
53
Buijs, B. and Sievers, H. (2011). Resource Security Risk in Perspective: Complexity and Nuance. Retrieved from
http://www.nachhaltigwirtschaften.at/e2050/e2050_pdf/reports/20111111_resource_security_risks_in_perspective
.pdf.
54
Conclusions drawn from the interview with Dr Günter Tiess and Dr Horst Hejny
55
Pinsent Masons LLP. (2013). Successful Joint Ventures in China. Retrieved from http://www.out-
law.com/en/topics/projects--construction/projects-and-procurement/successful-joint-ventures-in-china/.
0
20000
40000
60000
80000
100000
120000
140000
Production Demand
MetricTons
Rare Earth Supply and Demand 2013
China
The Rest of the World
Rest of the World Production + Chinese Export Quota
15. Europe’s Rare Earth Dependence on China: Future Perspectives
14 European Institute for Asian Studies
foreign companies in the mid- to long-term. As, however, companies operating in the field
of rare earths are often embedded in rigid supply chains, their limited flexibility might
prevent them, in particular in the short-term, from reversing their market entry. 56
Furthermore, as Günter Tiess pointed out, “companies still access rare earth elements in
China at a significant discount” and “strategic downstream manufacturing such as magnet
making continues to move to China, where access to rare earth elements remains cheapest
and most secure”.57
c.) Implications for the global rare earth prices
Figure 3 illustrates the evolution of international rare earth prices between 2008 and 2012.
The graph shows a slight drop in prices shortly after the Global Financial Crisis gained
momentum but indicates a quick recovery already by the second half of 2009. The
introduction of China’s export restrictions in 2010 was immediately reflected in skyrocketing
prices peaking in Q2 of 2011. From then onwards prices, however, started dropping again
and reached almost the level of before the price spike by early 2012.
Figure 3: The Evolution of rare earth prices 2008-2012, Bloomberg
From a classical economic perspective, the removal of export quotas, hence an international
supply increase in rare earth materials would, ceteris paribus, lead to dwindling prices.
However, the past has shown that the rare earth market formula seems to be more complex
and that there is no direct causal relation between China’s rare earth export rates and
global prices.58
Although the implementation of China’s export restrictions in 2010 were
followed by a price spike in the international rare earth market, prices started falling again –
contrary to prevailing expert predictions – before mining firms outside of China such as
Molycorp and Australia's Lynas augmented their production. 59
In an interview with the
investment platform InvestorIntel.com, the Australian expert on rare earth markets
Professor Dudley J. Kingsnorth gave an explanation of this phenomenon. According to him,
56
Conclusions drawn from the interview with Mr Duncan Freeman
57
Information received in the interview with Dr Günter Tiess and Dr Horst Hejny
58
Conclusions drawn from the interview with Mr Duncan Freeman
59
Els, Frik. (2014). Rare earth prices have turned. Retrieved from http://www.mining.com/rare-earth-prices-at-
turning-point-33322/.
16. Julia Ebner
European Institute for Asian Studies 15
China’s announcement of rare earth restrictions and the subsequently skyrocketing prices in
2010 and 2011 caused panicked Western businesses to start a huge stockpiling of rare
earths (perhaps equivalent to three or four years of consumption), partly by buying large
quantities of illegal rare earth materials from China. In 2012, the Chinese MIIT reported an
illegal rare earth mining output of over 40,000 tons at the fifth China Baotou Rare Earth
Industry Forum.60
These illegal mining and smuggling activities resulted in a significant
oversupply and declining rare earth prices. As a consequence, China has become more
proactive in locating and closing down illegal mining sites. In the meantime, the stockpiling
of rare earth concentrates has led to lowered global demand for rare earths, as many
companies have lived from their oversized inventories in recent years. 61 The imminent
depletion of those stockpiles in combination with the lifting of China’s export restrictions are
key factors of influence which are likely to shape the rare earth prices in the close future.
This means that, while the decreasing stockpiles would soon lead to rising demand levels
and thus to a tendency towards recovering prices, the WTO ruling would rather suggest a
downward trend in prices due to elevated supply levels. In the long term, other factors such
as rising global demand levels for ICT and clean technology products, the implementation of
laws integrating environmental costs into Chinese rare earth prices as well as the
development of alternative rare earth supplies, substitutes and recycling processes will
certainly play a crucial role in determining rare earth prices.
In fact, the Chinese rare earth industry has already been affected by the WTO ruling, as this
year’s profit drop of China's major rare earth producer Inner Mongolia Baotou Steel Rare-
Earth Group illustrates. The company’s profit saw a decline by more than 70 per cent to
69.38 million yuan (EUR 8.88 million) year on year in the first quarter of 2014, according to
a Xinhua article released by MOFCOM.62
The company’s falling profit can partly be attributed
to the WTO ruling: according to an executive from Baotou, producers feared a sharp decline
in prices as a consequence of the abolition of China’s export regulations, further
deteriorating the already unstable sector.63
Since investors were predicting falling prices,
they started selling off their company shares, consequentially triggering a self-fulfilling
prophecy. Dropping prices resulted in Inner Mongolia Baotou Steel Rare-Earth Group’s profit
drop which in return caused traded shares to fall by 4.14 percent (to 20.14 yuan per
share).64
d.) Implications for China’s environment
Although Western countries and the WTO consider China’s environmental concerns as a
“pretext for gaining advantage or increasing economic returns” 65
, the environmental
argument cannot be completely dismissed, as Duncan Freeman, senior research fellow at
the Brussels Institute for Contemporary China Studies stressed. Even if China’s industrial
policy has played a key role in the country’s export restrictions, the importance of China’s
60
China’s rare earth industry sees progress, challenges. (2013). Xinhua. Retrieved from
http://www.globaltimes.cn/content/802521.shtml.
61
InvestorIntel. (2013). Professor Dudley Kingsnorth’s bullish position on REE markets. Retrieved from
http://investorintel.com/rare-earth-intel/professor-dudley-kingsnorths-bullish-positive-position-on-ree-markets/.
62
MOFCOM. (2014). China’s rare earth firm Q1 profit slumps by 70 pct. Retrieved from
http://english.mofcom.gov.cn/article/newsrelease/counselorsoffice/westernasiaandafricareport/201404/201404005
57267.shtml.
63
Ibid.
64
China’s rare earth firm Q1 profit slumps 70 pct. (2014). Xinhua News. Retrieved from
http://news.xinhuanet.com/english/china/2014-04/16/c_133267764.htm.
65
Tanquintic-Misa, E. (2013). China’s Rare Earths Export Restrictions Defy Rules – WTO. Retrieved from
http://au.ibtimes.com/articles/518396/20131031/china-rare-earths-export-wto.htm#.VCVr3vmSx5I.
17. Europe’s Rare Earth Dependence on China: Future Perspectives
16 European Institute for Asian Studies
environmental concerns for shaping the country’s supply equation should not be
underestimated.66
Despite the substantial comparative advantage China enjoys vis-à-vis other rare-earth
producing countries thanks to its lax environmental policies, the Chinese government has
lately become increasingly aware of the environmental costs excessive mining has induced.
In its first White Paper on rare earth policies in 2012, Beijing confirmed that poorly
regulated rare earth mining and the use of outdated technology have caused severe
damage to the ecological environment, triggering water loss, soil erosion, acidification and
other forms of pollution and environmental degradation.67
For example, the centre of rare
earth mining, Baotou, faces hazardous water pollution, as mines around Baotou generate
around 10 million tonnes of highly acid and radioactive wastewater. 68
In particular,
increased cancer rates, climaxing in the so-called "cancer villages" along the Yellow River,
have led to public protests and stricter environmental standards.69
Negative externalities arising from rare earth mining are not yet reflected in China’s rare
earth prices70
. However, the integration of environmental costs is only a matter of time,
according to Mr Xie Wei.71
Once the integration of environmental externalities is included in
the price, potential changes to resource taxes and the closing down of illegal mines will
certainly render mining more expensive and thus less attractive for investors, the
environmental dimension will tend to become a major trigger of change affecting China’s
rare earth supply and thus the international rare earth market dynamics.
VI. Europe’s Role in International Rare Earth Market Dynamics
Chapter V has shown that China’s domestic and international mineral policies have
dramatically influenced the international market dynamics of rare earths. This chapter aims
at discussing Europe’s role in the international rare earth markets, addressing in particular
Europe’s potential to enjoy a bigger rare earth production share and higher degree of
independence in the future.
Despite all media-hyped pessimism, it is important to bear in mind that China’s rare earth
monopoly is only temporary. Europe’s power as a consumer is of course rather limited, as is
often the case in monopolistic and demand excess markets. This implies that only changes
on the supply side could challenge China’s quasi-monopoly and contribute to a more
competitive rare earth market. As a major and growingly important non-Chinese consumer
of rare earths, Europe should theoretically have a high incentive to invest in the future of its
rare earth supply.
In the mid- to long term, Europe could become more independent from China by taking
proactive measures to increase its primary supply and/or to decrease its current demand for
rare earth materials. First, Europe could promote and diversify its rare earth supply by
66
Information received in the interview with Mr Duncan Freeman
67
Information Service of the State Council of The People’s Republic of China. (2012). Situation and Policies of
China’s Rare Earth Industry. Retrieved from
http://ycls.miit.gov.cn/n11293472/n11295125/n11299425/n14676844.files/n14675980.pdf.
68
Massari, Stefania and Ruberti, Marcello. (2013). Rare earth elements as critical raw materials: Focus on
international markets and future strategies. Resources Policy 38, 36-43., p. 42
69
Liu, Lee. (2010). Made in China: Cancer Villages. Environment Magazine. Retrieved from
http://www.environmentmagazine.org/Archives/Back%20Issues/March-April%202010/made-in-china-full.html.
70
Information received in the interview with Mr Xie Wei
71
Ibid.
18. Julia Ebner
European Institute for Asian Studies 17
investing in rare earth resource exploitation, smelting and separating on European territory
or by creating alternative supply chains through strategic cooperation with other countries
such as the US, Japan and Australia. Second, Europe could decrease its demand for rare
earths by enhancing resource efficiency, increasing the rare earth recycling rate and
advancing research on potential substitutes. These strategies shall be examined in the
following two subchapters.
a.) Trends in Primary Sourcing and International Collaborations
During the past few years, Europe has initiated projects related to both primary sourcing
and international collaborations. There are currently two European rare earth extraction
projects which are in an advanced stage, one in Greenland (Kvanefjeld) 72
and one in
Sweden (Nora Kärr)73
. Furthermore various smaller early-stage exploration projects are
underway in multiple European countries.74
Thanks to Europe’s abundant, albeit underexplored, rare earth deposits, the EU could decide
to strengthen its position in the rare earth market, and thereby contribute to a more
balanced market competition and guarantee European supply security75
. Although the above
mentioned mining projects in Northern Europe are the result of extensive geological,
hydrometallurgical and environmental R&D, and although their mining potential is
considered as very promising, there are still several key obstacles to Europe’s primary rare
earth supply. One of the biggest challenges is posed by the high uranium and thorium
concentrations in these deposits. In addition to radioactivity-related problems, the EU has
currently insufficient processing and separation capacities. As there are no markets for
mixed rare earth element concentrates, mining companies would either have to build their
own capital-intensive and technically complex separation plants or cooperate with existing
facilities. 76
So far there are, however, only three rare earth separation and processing
companies in Europe: Rhodia Electronics and Catalysts (France), Treibacher Industrie AG
(Austria) and AS Silmet (Estonia).77
With adequate funding and the required permissions, European mining companies could
start extracting rare earth concentrates before 2020.78
It would, however, take investments
totalling at least five to six billion EUR in order to effectively revive rare earth mining in
Europe.79
While being very committed on a political level and supporting research on better
mining practices, the EU does not provide the financial resources to restart the European
mining sector. 80
Therefore, finance of such investments remains another unresolved
challenge; the question is: who would agree to finance the construction of new rare earth
mining and processing sites against the background of the high degree of uncertainty and
volatility of the rare earth market? Demand is hardly predictable and prices are unstable.81
Besides, investments in upstream activities are always riskier for European companies than
for Chinese companies due to their smaller size and the fact that they are not state-backed.
72
Greenland Minerals and Energy Ltd. (2014). Rare Earth Elements in Kvanefjeld. Retrieved from
http://www.ggg.gl/rare-earth-elements/rare-earth-elements-at-kvanefjeld/.
73
Tasman Metals Ltd. (2014). Norra Kärr Rare Element Project. Retrieved from
http://www.tasmanmetals.com/s/Norra-Karr.asp.
74
ERECON. (2014). Working Group I: Opportunities and road blocks for primary supply of rare earths in Europe.
Retrieved from http://ec.europa.eu/enterprise/policies/raw-materials/erecon/expertise/working-group-1_en.htm.
75
Information received in the interview with Dr. Günter Tiess and Dr. Horst Hejny
76
Ibid.
77
Cf. Massari, Stefania and Ruberti, Marcello. (2013). Rare earth elements as critical raw materials: Focus on
international markets and future strategies. Resources Policy 38, 36-43.
78
Ibid.
79
Information received in the interview with Prof. Dr. Arnold Tukker
80
Ibid.
81
Conclusions drawn from the interview with Prof. Dr. Arnold Tukker
19. Europe’s Rare Earth Dependence on China: Future Perspectives
18 European Institute for Asian Studies
As discussed in chapter II, China enjoys a wide range of comparative advantages over
Western countries in regards to rare earth mining.
The Kvanefjeld project in Southern Greenland required a capital investment of USD 810
million and the Swedish Norra Kärr incurred costs amounting to USD 290 million, both not
yet including rare earth separation plants.82
Paradoxically, China has become involved in
Kvanefjeld, a project aiming at promoting Europe’s internal mining potential and decreasing
the continent’s dependence on external sources. In March 2014, Greenland Minerals signed
a Memorandum of Understanding with China’s Non-Ferrous Metal Industry’s Foreign
Engineering and Construction Co. Ltd. (NFC) regarding possible separation of the rare earth
concentrates.83
From a business perspective, a strategic cooperation agreement with NFC,
global leader in rare earth separation technologies, could bring about various industrial
advantages. In particular, benefits could arise from Chinese financial investments, technical
cooperation and possible knowledge transfers. However, from a security perspective, the
collaboration is questionable, as it could be seen as a move towards a new form of
dependence on China and therefore as counterproductive for Europe’s supply diversification
goals. 84
A business partnership with NFC could potentially pave the way for future
involvement of China in Europe’s rare earth projects, helping China to gain even more
power in the field of rare earth separation instead of challenging its quasi-monopolistic
status quo. And yet, cooperation with China should not be dismissed altogether, as Europe
could benefit from knowledge and technology exchanges as well as joint venture
investments with the Chinese.
In the meantime, Europe has rather been leaning towards the developed world for possible
collaborations: there are initiatives of enhancing cooperation between the EU, Japan, the
US, and potentially also Australia and Canada. This could span from pure research
cooperation to the joint creation of an alternative supply chain. Since October 201185
, four
US-Japan-EU trilateral workshops on Critical Raw Materials have been organised by the
European Commission (EC), the US Department of Energy (DOE), Japan’s Ministry of
Economy, Trade and Industry (METI) and the Japanese New Energy and Industrial
Technology Development Organization (NEDO) in order to jointly address shortage problems
associated to rare earths and other critical materials. Participants suggested cooperation on
research-related and technological matters including geological mapping, environmental-
friendly extraction, separation technologies, recycling along the entire value-chain including
eco-design, end-of-life management, urban mining, rare earth substitutes, etc.86
These cooperation efforts between developed countries convey the image of a competition
for rare earths between China and the West. By teaming up with the US, Japan, Australia
and Canada and thereby marginalising and isolating China, Europe could miss out on
potentially beneficial opportunities for cooperation with China. The Chinese White Paper on
82
ERECON. (2014). Working Group I: Opportunities and road blocks for primary supply of rare earths in Europe.
Retrieved from http://ec.europa.eu/enterprise/policies/raw-materials/erecon/expertise/working-group-1_en.htm.
83
Reuters. (2014). Greenland Minerals Signs Memorandum of Understanding with China’s NFC, to form Fully-
Integrated Global Rare Earth Supply Chain. Retrieved from
http://uk.reuters.com/article/2014/03/24/idUKnMKWYY46va+1f0+MKW20140324.
84
Conclusions drawn from the interview with Mr Duncan Freeman
85
Trilateral EU-Japan-US Conference on Critical Materials for a Clean Energy Future. (2011). Summary Report.
Retrieved from
http://energy.gov/sites/prod/files/2013/05/f0/TRILATERAL_CRITICAL_MATERIALS_WORKSHOP_SummaryReportfin
al%2020111129.pdf.
86
Conclusions of the Third EU-US-JP Conference on Critical Minerals. (2013). Retrieved from
http://ec.europa.eu/research/industrial_technologies/pdf/trilateral-conclusions_en.pdf. p. 2-3
20. Julia Ebner
European Institute for Asian Studies 19
rare earths87
states that China is committed to technology and knowledge exchange with
industry experts from the US, the EU, Russia, Japan and other countries. Of course, the fact
that China benefits from its powerful position in the rare earth market and therefore only
has very limited incentives for cooperation with Europe88
should not be dismissed in the
debate. However, the EU could seek to enhance mutual trust on the rare earths issue and
establish reciprocally beneficial forms of cooperation with China. Potential areas of
cooperation reach from knowledge and technology transfers to shared initiatives in rare
earth rich regions across Europe, China or elsewhere. The following table shows potential
advantages of a bilateral cooperation on rare earth development for both the EU and China.
Advantages EU Advantages China
Chinese investments could help to revive the
EU’s dormant rare earth mining sector and
solve the question of financing rare earth
projects
Chinese collaboration with the EU and
investments in Europe’s rare earth
development could create good returns in
the long term without further increasing its
environmental burden
Knowledge transfer from China on cutting
edge mining technology could enhance the
EU’s mining capacities and competence
Knowledge transfer from the EU on
sustainable mining and environmental-
friendly technology transfers could help
China to make its own rare earth industry
more sustainable
Joint development of mining potential in
remote areas of Greenland or other
countries could decrease the EU’s supply
security risks
By participating in projects abroad and
assisting other countries in developing their
mining potential in the role of an advisor
China could make use of its competitive
advantage
b.) Recycling, Substitutes and Emerging Alternatives in Europe
According to the European Rare Earths Competency Network (ERECON), the EU’s goal is to
achieve a higher degree of independence not only through enhancing primary supply but
also through decreasing the demand for rare earths. European countries have therefore
intensified their efforts to find solutions for more efficient use, end-of-life recycling or re-
using of rare earths as well as potential substitutes.89
The past few years have brought about significant innovations in Europe’s mining and
refining sector and in the field of nanotechnology which could help to recycle, re-use and
replace rare earths from electronic products in the mid- to long term. For example,
developments such as the shift from tri-phosphor lightening to light-emitting diodes (LED)
have led to lower use of yttrium, europium and terbium, all of which fall under the category
of heavy rare earths. The use of heavy rare earths per unit was also substantially reduced in
permanent Neodymium (NdFeB) magnets. 90
Furthermore researchers at Northeastern
University have developed strong magnetic material in 2012 which does not require the use
87
Information Service of the State Council of The People’s Republic of China. (2012). Situation and Policies of
China’s Rare Earth Industry. Retrieved from
http://ycls.miit.gov.cn/n11293472/n11295125/n11299425/n14676844.files/n14675980.pdf.
88
Information received in the interview with Dr. Günter Tiess and Dr. Horst Hejny
89
ERECON. (2014). Working Group II: European rare earths resource efficiency and recycling. Retrieved from
http://ec.europa.eu/enterprise/policies/raw-materials/erecon/expertise/working-group-2_en.htm.
90
Sims, Jim. (2014). EIAS Briefing Seminar Europe’s Rare Earth Dependence on China: Future Perspectives.
Retrieved from http://eias.org/sites/default/files/EIAS_Presentation_Sims_updated_14.10.2014.pdf.
21. Europe’s Rare Earth Dependence on China: Future Perspectives
20 European Institute for Asian Studies
of rare earths.91
And yet, although rare earth substitutes are available for many products,
they still tend to be less effective. 92
For example, common electromagnets are used to
replace permanent rare earth magnet for induction motors but they are significantly larger
and heavier.
Likewise, rare earth recycling is still in a very early stage. At present, recycling rates and
alloys from end-of-life products tend to be very low (less than 1 per cent), mainly as a
result of technical and economic hindrances.93
Currently there are recycling processes for
phosphors, permanent NdFeB magnets, industrial residues, nickel metal hydride batteries
and various other rare earth containing products.94
And yet, so far only phosphors and
batteries can be recycled on an industrial scale. Theoretically, the recycling market for rare
earths in Europe has great potential, as the EU is a significant consumer of rare earth
containing products. However, an integrated recycling process would require a detailed
market analysis of EU’s rare earth consumption, taking into account historical as well as
predicted future sales. As there is, however, only limited data on the consumption of
products which contain rare earth materials (especially in regards to rare earth magnets),
market analyses are currently not available for the EU.95
According to an expert on recycling from the private sector, who wanted to remain
anonymous, the biggest challenge for recycling rare earth elements is still posed by
collection. Rare earth elements are usually dispersed everywhere in little units. For
example, the magnets used in cell phone speakers only contain very small quantities of rare
earths; this naturally renders collection logistics very difficult and often not economically
viable.96
Despite these challenges, companies such as Umicore (Belgium)97
, Saubermacher
(Austria)98
and others have initiated projects for the recycling of electronic devices such as
phones and laptops.
An advanced rare earth recycling system would not only provide the EU with advantages
related to a higher supply security but also with lower environmental burdens compared to
primary production, cheaper sources of material and less radioactive waste.99
Strategies and
methods for recycling (urban mining) are therefore explored both at the EU level and at a
private company level. In 2011, the EU-Japan Science and Technology Agreement entered
into force and paved the way for intensive research collaboration on rare earths. In 2013,
320 research teams participated in projects with the aim of finding rare earth substitutes
funded jointly by the EU and Japan.100
An example for innovative projects in the private sector is Umicore’s and Rhodia’s (now
Solvay) joint development of a recycling process for rechargeable batteries. The process
91
Wells, Steve. (2013). Emerging Alternatives to Rare Earth Elements. Futurium. European Commission. Retrieved
from https://ec.europa.eu/digital-agenda/futurium/en/node/1637.
92
US Geological Survey. (2014). Mineral Commodity Summaries. Rare Earths. Retrieved from
http://minerals.usgs.gov/minerals/pubs/commodity/rare_earths/mcs-2014-raree.pdf.
93
Information received in the interview with Dr. Günter Tiess and Dr. Horst Hejny
94
Binnemans, K., Jones, P. et al. (2013). Recycling of rare earths: a critical review. Elsevier Journal of Cleaner
Production. Retrieved from
http://www.kuleuven.rare3.eu/papers/JCLEPRO_Binnemans_REE_Recycling_May2013.pdf.
95
Information received in the interview with Dr. Günter Tiess and Dr. Horst Hejny
96
Information received in an interview with an expert on rare earths recycling from the private sector
97
Umicore. (2014). Rechargeable Batteries (storing energy). Retrieved from
http://www.umicore.com/en/cleanTechnologies/batteries/.
98
Saubermacher. (2014). Leistungen: Entsorgungslösungen. Retrieved from
http://www.saubermacher.at/de/leistungen/#elektroaltgeraeteentsorgung.
99
Information received in the interview with Dr. Günter Tiess and Dr. Horst Hejny
100
Rhode, Barbara. (2013). The EU-Japan Science, Research and Innovation coopearation under the EU-Japan S&T
Agreement. Retrieved from http://www.concertjapan.eu/system/files/TheEU-
JapanScienceResearchInnovationCooperation_EUDelegationJapan%20%5BUyumluluk%20Modu%5D.pdf.
22. Julia Ebner
European Institute for Asian Studies 21
allows for the recovery of rare earths from Nickel Metal Hydride (NiMH) rechargeable
batteries.101
Umicore first separates the nickel and iron from the rare earths and processes
them into high grade concentrate at its new battery recycling plant in Antwerp (Hoboken).
The rare earth concentrate is then refined and transformed into rare earth materials at
Rhodia’s plant in La Rochelle. According to Sybolt Brouwer, General Manager of the Battery
Recycling and Recycling Development at Umicore, “this is the first industrial process that
closes the loop of the rare earths contained in NiMH batteries.” The recycling process can be
applied to different kinds of NiMH batteries, ranging from portable applications of
rechargeable AA and AAA batteries used in cordless phones, toys and games to batteries
used in hybrid electric vehicles.102
Despite all these improvements, recycling can currently only contribute a small part to a
coherent raw materials policy.103
A circular economy for rare earths is not possible at this
point, as the demand for rare earth elements applications is still growing and new materials
have to enter the economy. This means that recycling can only happen up to a certain level
(about 25-30 per cent) due to the discrepancy between the materials needed and the
materials which can currently be recycled.104
It can be concluded that although there is still
potential for more innovations in the area of rare earth substitutes and recycling, primary
domestic production or external sourcing will be needed to meet the growing demand for
rare earth products in the European economy.
VII. Future Predictions and Scenario Analysis
Most future market predictions for the annual growth of rare earth consumption range from
5 to 9 per cent over the next 25 years. 105
In total figures this would mean a worldwide rare
earth demand amounting to 160,000-208,000 metric tons by 2020. However, estimations
made in a research report on the future of China’s rare earth industry are far less optimistic,
with rare earth demand predictions of 0.3 million metric tons for 2020106
, hence exceeding
estimated production rates for 2020 (210,000 metric tons) by far.107
Figure 4 takes into account these divergent future estimations by illustrating different
scenarios. While the best case scenario of global demand shows the lower end of expert
predictions, the worst case scenario shows the very upper end of expert estimations. The
chart displays that in the best case demand scenario the expected global production for the
years to come would be sufficiently high, while the worst case scenario raises concern about
a potential inequality between the growth of demand and the growth of production. Still,
even the best case scenario does not necessarily mean that the demand for every rare
101
Rhodia, Solvay Group. (2011). Umicore and Rhodia develop unique rare earth recycling process for rechargeable
batteries. Retrieved from
http://www.rhodia.com/en/news_center/news_releases/Umicore_rare_earth_160611.tcm.
102
Rhodia, Solvay Group. (2011). Umicore and Rhodia develop unique rare earth recycling process for rechargeable
batteries. Retrieved from
http://www.rhodia.com/en/news_center/news_releases/Umicore_rare_earth_160611.tcm.
103
Information received in the interview with Dr. Günter Tiess and Dr. Horst Hejny
104
Information received in an interview with an expert on rare earths recycling from the private sector
105
Alonso, E., Sherman, A. et al. (2012). Evaluating rare earth element availability: A case with revolutionary
demand from clean technologies. Environmental science and technology, 46, 3406-3414. Retrieved from
http://pubs.acs.org/doi/pdf/10.1021/es203518d.
106
Research Report on Rare Earth (RE) Industry in China, 2014-2019. (2014). China Research and Intelligence.
Retrieved from http://www.rnrmarketresearch.com/research-report-on-rare-earth-re-industry-in-china-2014-2018-
market-report.html.
107
Rare earth production in China and outside. (2014). Statista.com. Retrieved from
http://www.statista.com/statistics/279953/rare-earth-production-in-china-and-outside/.
23. Europe’s Rare Earth Dependence on China: Future Perspectives
22 European Institute for Asian Studies
earth element can be met, as this chart only shows the aggregate rare earth demand and
supply. Especially, demand for neodymium and dysprosium is expected to soon exceed
global supply108
, potentially resulting in price instabilities for high tech and clean technology
products dependant on these materials.
It is important to note that demand for individual rare earth elements does not grow at
equal pace. Instead, the growth for each rare earth element is usually in accordance with
the growth in markets for the respective derivative products. Nonetheless, supply increases
or decreases for certain rare earth elements often translate directly into supply increases or
decreases for other rare earth elements as a result of co-mining.109
Figure 4: Future Scenarios of Rare Earth Supply and Demand 2013-2020, author’s compilation of Alonso
et al., Statista.com and China Research and Intelligence
As discussed in chapter V, China’s targets to promote sustainability and better
environmental standards in its mining sector could lift production costs and ultimately result
in a general surge of rare earth prices. In addition to that, Chinese heavy rare earth
reserves are expected to be depleted in about two decades. 110
Although rare earth
production outside of China will most probably increase during the next few years (mainly
due to the reopening of the US’ Mountain Pass mine and Australia’s Mount Weld mine),
heavy rare earths can only be mined in very small quantities. At both Mountain Pass and
Mount Weld, the light rare earths Cerium, Lanthanum, Neodymium and Praseodymium
account for at least 95 per cent of the extracted materials. Once launched, the Kvanefjeld
site in Greenland could become an important future source of heavy rare earth production:
about 12 per cent of its rare earth deposits consist of heavy rare earth elements.111
New
sources for primary supply, albeit promising, might not be enough to avoid shortages and
high costs in the rare earth market. Additional measures aiming at decreasing the demand
for rare earths and in particular heavy rare earth elements should be taken proactively. The
108
Wells, Steve. (2013). Emerging Alternatives to Rare Earth Elements. Futurium. European Commission. Retrieved
from https://ec.europa.eu/digital-agenda/futurium/en/node/1637.
109
Alonso, E., Sherman, A. et al. (2012). Evaluating rare earth element availability: A case with revolutionary
demand from clean technologies. Environmental science and technology, 46, 3406-3414. Retrieved from
http://pubs.acs.org/doi/pdf/10.1021/es203518d.
110
Mackie Research Capital Corporation. (2011). Rare Earth Industry Update. Retrieved from
http://www.ggg.gl/userfiles/file/Broker_Research_Reports/Rare_Earth_Mackie_Industry_Update.pdf.
111
UNCTAD. (2014). Commodities at a Glance. Special issue on rare earths. Retrieved from
http://unctad.org/en/PublicationsLibrary/suc2014d1_en.pdf. p.36
0
50000
100000
150000
200000
250000
300000
350000
2013 2014 2015 2016 2017 2018 2019 2020
MetrictonsofREO
Future Scenarios
Global Demand Best Case
Global Demand Worst Case
Global Production Expected
24. Julia Ebner
European Institute for Asian Studies 23
costs of insufficient supply of heavy rare earth elements such as dysprosium were already
demonstrated in the price spikes between 2006 and 2011.112
According to British trend analyst Steve Wells, it is not unlikely that rare-earth dependent
industries will see an increase in innovations for rare earth substitutes during the next
decades. Restrictions in the supply chain can be a possible trigger for innovation and thus
an accelerator for the supply of alternative technologies, approaches or materials.113
The
innovation concept of S-curves, as shown in Figure 5, suggests four possible patterns for
technology transitions, depending on whether radical or incremental innovations occur and
on whether there is a fluent or a disruptive transition. This concept used in innovation
studies is particularly interesting when looking at current and potential future trends in the
field of rare earths.
Figure 5: Innovation Patterns, ETRIA
At the current stage it seems that all transitions are still possible in the rare earth market,
though the consequences would potentially differ greatly: while sustaining innovation would
tend to have positive effects on the rare earth market dynamics in both the case of radical
or incremental innovation, any disruptive form of technology transition could have fatal
consequences on rare earth supply security and global rare earth prices. It would imply that
the markets for rare-earth dependant products would see a stagnation before production
could be resumed thanks to radical or incremental innovations in reaction to such an acute
rare earth crisis. Whereas incremental innovations would build on the enhancement of
existing alternatives, radical innovation would provide the clean technology and high tech
sector with completely unprecedented solutions. This second case could mean that China
would almost instantly lose its powerful status as a quasi-monopolistic provider of rare earth
elements.
112
Moss, R., Tzimas, E. et al. (2011). Critical metals in strategic energy technologies. JRC scientific and technical
reports. Retrieved from http://setis.ec.europa.eu/newsroom-items-folder/jrc-report-on-criticalmetals-in-strategic-
energy-technologies/at_download/Document.
113
Information received in the interview with Steve Wells
25. Europe’s Rare Earth Dependence on China: Future Perspectives
24 European Institute for Asian Studies
VIII. Conclusions and Recommendations
Like in any market, the future of the rare earth market depends mainly on the changes of
its supply and demand side. The previous chapters have examined recent trends on both
sides of the market and will therefore serve as a basis for the conclusions drawn in this
scenario analysis. The following scenario analysis (Figure 6) explains the four possible
combinations of supply and demand developments in the rare earth market and attempts to
draw conclusions for each scenario.
Figure 6: Scenario Analysis, author’s compilation
COMPETITIVE MARKET
•China is compliant with world bodies and
other governments about international access
to rare earth pricing and supply
•In the meanwhile, the EU makes fast
progress in advancing rare earth substitutes
and/or rare earth recycling and thereby
decreases its rare earth demand dramatically
•New inter-governmental and private sector
partnerships are formed to discover and
exploit alternatives.
•Prices for rare earths fall drastically
China loses it's powerful position in the market
for rare earths to a large extent, as demand
decreases and gloabl supply increases
ACCEPTABLE DEPENDENCE
•China is compliant with world bodies and
other governments about international access
to rare earths
•The search for rare earths substitutes and
recycling methods are largely unsuccessful or
too limited in its extent to counterbalance the
rapidly rising demand for clean technology
products in the EU
•Efforts to maintain the same pace of supply
and demand increases by further putting
pressure on China and developing new
domestic primary sources of supply
•EU's dependance on China , however,
remains significant
INCREASING INDEPENDENCE
•China is increasingly belligerent to world
bodies and other governments about
international access to rare earths, pricing and
supply
•EU and other western markets do not
cooperate enough on the development of
primary sources but find effective ways to
decrease the demand by sustituting or
recycling rare earths
•China remains the dominant player but due
to dropping demand levels its influence and
power in the rare earth market decrease
•Prices are not as reactive to Chinese supply
decisions anymore and thus more stable
DEPENDENCE AND SHORTAGE
•China is increasingly belligerent to world
bodies and other governments about
international access to rare earths, pricing and
supply
•An uneasy status quo is retained leading to a
lack of confidence in reliability of supply
•China remains the most dominant player in
the rare earth market
•Increasing economic & political tension as EU
and US markets continue to be over-reliant on
Chinese imports
•Status quo retained or further exacberated
•New price fluctuarions and price spikes to be
expected
Decreasing
Demand
Increasing
Demand
Decreasing
Supply
Increasing
Supply
26. Julia Ebner
European Institute for Asian Studies 25
To conclude, Europe is confronted with an increasingly delicate situation regarding its mid-
to long-term rare earth supply security mainly as a result of rising global and domestic
demand levels for rare earths. In particular, Europe’s clean technology sector is at stake
due to global shortages of heavy rare earth elements, sensitivity of the rare earth market
and limited availability of sustainable substitutes and effective recycling methods. Although
the recent WTO ruling against China will certainly decrease current pressure on the
international rare earth market, Chinese heavy rare earths could be depleted within the
next two decades. Therefore relying further on China’s rare earth supply (even against the
background of the WTO decision in favour of Europe, the US and Japan) cannot be a
sustainable strategy. This makes it necessary for the EU to take measures on an EU level
but also on an international level in order to secure its future access to rare earth materials.
On an EU level, it seems important that Europe seeks to create a consolidated mineral
policy and integrates its rare earth policies into a broader resources strategy. It should
furthermore make better use of existing expertise across the fields of research, politics and
business by interlinking sectorial findings. In order to avoid shortages and hefty price
fluctuations, investments in new rare earth deposits should be coupled with the
development of more effective substitutes and recycling processes. Finding sustainable
substitutes for rare earths, creating higher resource efficiency and increasing recycling rates
could help to decrease Europe’s strongly rising demand for rare earths.
On an international level, European cooperation with other countries and diversification of
supply can provide solutions for the threat of sudden supply shortages or price spikes.
Although Europe is currently upgrading its cooperation with Australia, US, Japan and
Canada to jointly develop an alternative supply chain, it should also seek to enhance Sino-
European cooperation on the development of new rare earth sources. Building an anti-China
block with the US, Japan and Australia could make China even less cooperative, while
building mutual trust, establishing knowledge and technology transfers and initiating joint
rare earth projects could help Europe to gain funding and expertise for the development of
its rare earth sources. For example, the EU should seek to encourage the formation of Sino-
European joint ventures and provide China with adequate incentives to further increase its
investments in Europe’s re-emerging rare earths sector. As shown in chapter VI, Sino-
European cooperation could result in mutually beneficial agreements for rare earth mining,
processing and separation operations.
27. Europe’s Rare Earth Dependence on China: Future Perspectives
26 European Institute for Asian Studies
IX. Bibliography
Alonso, E., Sherman, A. et al. (2012). Evaluating rare earth element availability: A case with
revolutionary demand from clean technologies. Environmental science and technology, 46, 3406-
3414. Retrieved from http://pubs.acs.org/doi/pdf/10.1021/es203518d.
Alves, Ana. (2013). China’s Economic Statecaft and African Mineral Resources: Changing Modes of
Engagement. South African Institute for International Affairs. Occasional Paper No 131, p.5
Baotou National Rare-Earth Hi-Tech Industrial Development Zone (n.d.). Rare Earth: An
Introduction. Retrieved from http://www.rev.cn/en/int.htm.
Binnemans, K., Jones, P. et al. (2013). Recycling of rare earths: a critical review. Elsevier Journal
of Cleaner Production. Retrieved from
http://www.kuleuven.rare3.eu/papers/JCLEPRO_Binnemans_REE_Recycling_May2013.pdf.
Blakely, C., Cooter, J. et al. (n.d). Rare Earth Metals & China. Gerald R. Ford School of Public Policy
Brennan, Eliot. (2012). Rare earths – the next oil. Asian Times. Retrieved from
http://www.atimes.com/atimes/China_Business/NC16Cb01.html.
Buijs, B. and Sievers, H. (2011). Resource Security Risk in Perspective: Complexity and Nuance.
Retrieved from
http://www.nachhaltigwirtschaften.at/e2050/e2050_pdf/reports/20111111_resource_security_risks_i
n_perspective.pdf.
China State Council. (2006). Instruction for mineral resource development: Beijing, China, China
State Council Circular 108. December 31, 5 p. (In Chinese).
Conclusions of the Third EU-US-JP Conference on Critical Minerals. (2013). Retrieved from
http://ec.europa.eu/research/industrial_technologies/pdf/trilateral-conclusions_en.pdf.
Chu, Daye. (2014). Rare Earth Output Cap Raised. The Global Times. Retrieved from
http://www.globaltimes.cn/content/872512.shtml.
Dalton, Matthew and Mauldin, William. (2014). WTO Confirms China Loses Rare-Earths Case. The
Wall Street Journal. Retrieved from
http://online.wsj.com/news/articles/SB10001424052702304418404579463073051039380.
Davis, Bob. (2014). China’s State-Owned Sector Gets a Boost. The Wall Street Journal. Retrieved
from http://online.wsj.com/articles/SB10001424052702303636404579396933232035544.
Els, Frik. (2014). Rare earth prices have turned. Retrieved from http://www.mining.com/rare-
earth-prices-at-turning-point-33322/.
Embassy of the People’s Republic of China to the United States of America. (2012). Situtation and
Policies of China’s Rare Earth Industry. Retrieved from http://www.china-
embassy.org/eng/zt/bps/t943727.htm.
ERECON. (2014). Rare earth in Europe. Retrieved from
http://ec.europa.eu/enterprise/policies/raw-materials/erecon/index_en.htm.
ERECON. (2014). Working Group I: Opportunities and road blocks for primary supply of rare earths
in Europe. Retrieved from http://ec.europa.eu/enterprise/policies/raw-
materials/erecon/expertise/working-group-1_en.htm.
ERECON. (2014). Working Group II: European rare earths resource efficiency and recycling.
Retrieved from http://ec.europa.eu/enterprise/policies/raw-materials/erecon/expertise/working-
group-2_en.htm
European Commission. (2014). Defining ‘critical’ raw materials. Retrieved from
http://ec.europa.eu/enterprise/policies/raw-materials/critical/index_en.htm.
28. Julia Ebner
European Institute for Asian Studies 27
Farooki, Masuma. China and mineral demand – more opportunities than risk?. Polinares Working
Paper. n.75. Retrieved from http://www.polinares.eu/docs/d5-1/polinares_wp5_chapter5_4.pdf.
Gravgaard, Anna. (2013). Greenland’s Rare Earths Gold Rush. Foreign Affairs. The Council of
Foreign Relations. Retrieved from http://www.foreignaffairs.com/features/letters-from/greenlands-
rare-earths-gold-rush.
Greenland Minerals and Energy Ltd. (2014). Rare Earth Elements in Kvanefjeld. Retrieved from
http://www.ggg.gl/rare-earth-elements/rare-earth-elements-at-kvanefjeld/.
Hayes-Labruto, L., Schillebeeckx, S. et al. (n.d.) Contrasting Perspectives on China’s Rare Earth
Policies: Refraiming the Debate through a Stakeholder Lens. Retrieved from
http://www.academia.edu/2779606/Contrasting_Perspectives_on_Chinas_Rare_Earths_Policies_Refra
ming_the_Debate_through_a_Stakeholder_Lens.
Humphries, Marc. (2013). Rare Earth Elements: The Global Supply Chain. Congressional Research
Service. CRS Report for Congress. p.2.
Information Service of the State Council of The People’s Republic of China. (2012). Situation and
Policies of China’s Rare Earth Industry. Retrieved from
http://ycls.miit.gov.cn/n11293472/n11295125/n11299425/n14676844.files/n14675980.pdf.
InvestorIntel. (2013). Professor Dudley Kingsnorth’s bullish position on REE markets. Retrieved
from http://investorintel.com/rare-earth-intel/professor-dudley-kingsnorths-bullish-positive-position-
on-ree-markets/.
Jha, Saurav. (2014). China’s Rare Earths Advantage. The Diplomat. Retrieved from
http://thediplomat.com/2014/04/chinas-rare-earths-advantage/.
Jiji.(2014, March 24). Japan, US, EU win rare earths dispute over China. The Japan Times.
Retrieved from http://www.japantimes.co.jp/news/2014/03/26/business/japan-u-s-eu-win-rare-earth-
dispute-with-china/#.U0zgglcgRZg.
Liu, Lee. (2010). Made in China: Cancer Villages. Environment Magazine. Retrieved from
http://www.environmentmagazine.org/Archives/Back%20Issues/March-April%202010/made-in-china-
full.html.
Mackie Research Capital Corporation. (2011). Rare Earth Industry Update. Retrieved from
http://www.ggg.gl/userfiles/file/Broker_Research_Reports/Rare_Earth_Mackie_Industry_Update.pdf.
Mancheri, Nabeel, Sundaresan, Lalitha et al. (2013). Dominating the World: China and the Rare
Earth Industry. National Institute of Advanced Studies. Retrieved from
http://threeconsulting.com/pdfs/China-rare-earth-strategyin-wHighlights-.pdf.
Massari, Stefania and Ruberti, Marcello. (2013). Rare earth elements as critical raw materials:
Focus on international markets and future strategies. Resources Policy 38, 36-43.
MOFCOM. (2014). China’s rare earth firm Q1 profit slumps by 70 per. Retrieved from
http://english.mofcom.gov.cn/article/newsrelease/counselorsoffice/westernasiaandafricareport/20140
4/20140400557267.shtml.
MOFCOM. (2014). Principal of Department of Treaty and Law of MOFCOM Gives a Speech on WTO’s
Panel Report on the Case of the US, EU and Japan’s Action Against China’s Export Management
Measures of Relevant Rare Earth, Tungsten and Molybdenum Products. Retrieved from
http://english.mofcom.gov.cn/article/newsrelease/policyreleasing/201404/20140400538135.shtml.
Panda, Ankit. (2014). WTO Finds China’s Rare Earth Export Restrictions in Violation of International
Trade Law. The Diplomat. Retrieved from http://thediplomat.com/2014/03/wto-finds-chinese-rare-
earth-export-restrictions-in-violation-of-international-trade-law/.
Pinsent Masons LLP. (2013). Successful Joint Ventures in China. Retrieved from http://www.out-
law.com/en/topics/projects--construction/projects-and-procurement/successful-joint-ventures-in-
china/.
29. Europe’s Rare Earth Dependence on China: Future Perspectives
28 European Institute for Asian Studies
Research Report on Rare Earth (RE) Industry in China, 2014-2019. (2014). China Research and
Intelligence. Retrieved from http://www.rnrmarketresearch.com/research-report-on-rare-earth-re-
industry-in-china-2014-2018-market-report.html.
Reuters. (2014). Greenland Minerals Signs Memorandum of Understanding with China’s NFC, to
form Fully-Integrated Global Rare Earth Supply Chain. Retrieved from
http://uk.reuters.com/article/2014/03/24/idUKnMKWYY46va+1f0+MKW20140324.
Rhode, Barbara. (2013). The EU-Japan Science, Research and Innovation coopearation under the
EU-Japan S&T Agreement. Retrieved from http://www.concertjapan.eu/system/files/TheEU-
JapanScienceResearchInnovationCooperation_EUDelegationJapan%20%5BUyumluluk%20Modu%5D.p
df.
Rhodia, Solvay Group. (2011). Umicore and Rhodia develop unique rare earth recycling process for
rechargeable batteries. Retrieved from
http://www.rhodia.com/en/news_center/news_releases/Umicore_rare_earth_160611.tcm.
Saubermacher. (2014). Leistungen: Entsorgungslösungen. Retrieved from
http://www.saubermacher.at/de/leistungen/#elektroaltgeraeteentsorgung.
Sievers, Henrike and Tercero, Luis. (2012). European Dependence on and concentration tendencies
of the material production. Polinares EU Policy on Natural Resources. Retrieved from
http://www.polinares.eu/docs/d2-1/polinares_wp2_chapter2.pdf.
Sims, Jim. (2014). EIAS Briefing Seminar Europe’s Rare Earth Dependence on China: Future
Perspectives. Retrieved from
http://eias.org/sites/default/files/EIAS_Presentation_Sims_updated_14.10.2014.pdf.
Statista. (2013). Rare earth reserves worldwide as of 2013, by country (in 1,000 metric tons of
REO). Retrieved from http://www.statista.com/statistics/277268/rare-earth-reserves-by-country/.
Tanquintic-Misa, E. (2013). China’s Rare Earths Export Restrictions Defy Rules – WTO. Retrieved
from http://au.ibtimes.com/articles/518396/20131031/china-rare-earths-export-
wto.htm#.VCVr3vmSx5I.
Tasman Metals Ltd. (2014). Norra Kärr Rare Element Project. Retrieved from
http://www.tasmanmetals.com/s/Norra-Karr.asp.
The State Council Information Office of the People’s Republic of China. (2012). III. Effectively
Protecting and Rationally Utilizing Rare Earth Resources. Retrieved from
http://www.scio.gov.cn/zxbd/nd/2012/Document/1175401/1175401_4.htm.
Tiess, Günter. (2011). General and International Mineral Policy: Focus: Europe. Vienna: Springer,
1st Edition.
Trilateral EU-Japan-US Conference on Critical Materials for a Clean Energy Future. (2011).
Summary Report. Retrieved from
http://energy.gov/sites/prod/files/2013/05/f0/TRILATERAL_CRITICAL_MATERIALS_WORKSHOP_Sum
maryReportfinal%2020111129.pdf.
Tse, Pui-Kwan. (2011). China’s Rare Earth Industry. US Geological Survey. Open File Report 2011-
1042.
Umicore. (2014). Rechargeable Batteries (storing energy). Retrieved from
http://www.umicore.com/en/cleanTechnologies/batteries/.
UNCTAD. (2014). Commodities at a Glance. Special issue on rare earths. Retrieved from
http://unctad.org/en/PublicationsLibrary/suc2014d1_en.pdf. p.36
US Geological Survey. (2014). Mineral Commodity Summaries. Rare Earths. Retrieved from
http://minerals.usgs.gov/minerals/pubs/commodity/rare_earths/mcs-2014-raree.pdf.
30. Julia Ebner
European Institute for Asian Studies 29
Wells, Steve. (2013). Emerging Alternatives to Rare Earth Elements. European Commission.
Retrieved from https://ec.europa.eu/digital-agenda/futurium/en/content/emerging-alternatives-rare-
earth-elements
WTO. (2014). China – Measures Related to the Exportation of Rare Earths, Tungsten and
Molybdenum. Retrieved from http://www.wto.org/english/tratop_e/dispu_e/cases_e/ds431_e.htm.
Xiaojing, Liu. (2014). China to Form Two Rare Earth Metals Conglomerates. Caixin Online.
Retrieved from http://english.caixin.com/2014-08-07/100714129.html.
X. List of Figures
Figure 1: European Commission: Raw Materials Criticality Analysis 2010. Defining ‘critical raw
materials’ (2014). Retrieved from http://ec.europa.eu/enterprise/policies/raw-
materials/critical/index_en.htm.
Figure 2: Authors compilation of data from USGS Mineral Commodity Survey 2013, MOFCOM , Arafura
Resources Limited and Avalon Rare Earth Metals Inc. Data retrieved from
http://minerals.usgs.gov/minerals/pubs/mcs/2014/mcs2014.pdf,
http://avalonraremetals.com/news_media/industry_info/index.php?content_id=375,
http://english.mofcom.gov.cn/article/policyrelease/buwei/201301/20130108515230.shtml and
http://www.arultd.com/rare-earths/supply-demand.html
Figure 3: The Evolution of rare earth prices 2008-2012. Bloomberg. Retrieved from
http://www.marketoracle.co.uk/Article33315.html
Figure 4: Author’s compilation of Alonso et al., Statista.com and China Research and Intelligence. Data
retrieved from http://www.statista.com/statistics/279953/rare-earth-production-in-china-and-outside/,
http://www.rnrmarketresearch.com/market-research-report-on-global-and-chinese-rare-earth-
industry-2009-2019-market-report.html and Alonso, E., Sherman, A. et al. (2012). Evaluating rare
earth element availability: A case with revolutionary demand from clean technologies. Environmental
science and technology, 46, 3406-3414. Retrieved from
http://pubs.acs.org/doi/pdf/10.1021/es203518d.
Figure 5: ETRIA. (2008). Personal Report of ETRIA “TRIZ Future 2007” Conference. Retrieved from
http://www.osaka-
gu.ac.jp/php/nakagawa/TRIZ/eTRIZ/eforum/e2007Forum/eETRIATFC2007Rep/eETRIATFC2007TNRep.
html
31. Europe’s Rare Earth Dependence on China: Future Perspectives
30 European Institute for Asian Studies
XI. List of Interviewees
Prof. Dr. Arnold Tukker, Chair of the ERECON Working Group III, Director and professor of
Industrial Ecology, CML, Leiden University
Dipl. Ing. Dr. Günter Tiess, Director of MinPol KG - Agency for International Minerals Policy,
Senior Researcher at the Department of Mineral Resources and Petroleum Engineering of
Montanuniversitaet Leoben, Chair of the ERECON Working Group 1
Dr. Horst Hejny, Director of MinPol KG - Agency for International Minerals Policy, Project
manager of the EU-funded I²Mine project, Deputy Chair of the ERECON Working Group 1
Coraline Goron, PhD Candidate at Erasmus Mundus GEM PhD School, focusing on Chinese
environmental policies
Duncan Freeman, Senior Research Fellow at Brussels Institute of Contemporary China
Studies, speaker at the Conference "EU-China Economic Trade Relations: Cooperation or
Competition for Raw Materials" in 2012
Xie Wei, Second General at the Economic & Commercial Counsellor's Office of the Mission of
China to the European Union
Steve Wells, working at Fast Future/Informing Choices Ltd, Futurium of the European
Commission
Anonymous expert on rare earths recycling of a leading private sector materials technology
group
XII. Acknowledgements
First of all, I would like to express my gratitude for the help and guidance offered by my
supervisor David Fouquet. Furthermore I would like to thank all the interviewees for their
time and attention. Dipl. Ing. Dr. Günter Tiess, Dr. Horst Hejny, Coraline Goron, Duncan
Freeman, Xie Wei, Prof. Dr. Arnold Tukker, Steve Wells gave me very valuable insights into
the rare earths markets and helped me to assess some of the current trends in China and
Europe. My appreciation also goes to Mr Jim Sims and Prof. Olivier Arifon who provided me
with valuable feedback. Finally, I would like to thank Jim Stoopman, Alberto Turkstra and all
other programme coordinators and researchers at EIAS for their precious feedback, their
assistance in interviews and their comprehensive support.