Loading...
|
Please use this identifier to cite or link to this item:
https://nccur.lib.nccu.edu.tw/handle/140.119/154998
|
| Title: | 循環經濟作為歐盟關鍵原料供應鏈去風險化策略的可行性探討 — 以電動車鋰電池為例
The circular economy as a potential ‘de-risking’ strategy for critical raw materials supply in the EU : The case of electric vehicle lithium-ion battery recycling |
| Authors: | 艾瑪
Armer, Emma |
| Contributors: | 蘇卓馨
Su, Cho-Hsin
艾瑪
Emma Armer |
| Keywords: | 歐洲聯盟
關鍵原料
循環經濟
去風險策略
依賴
回收
電動汽車電池
彈 力
European Union
Critical raw materials
Circular economy
De-risking strategy
Dependence
Recycling
Electric vehicle batteries
Resilience |
| Date: | 2024 |
| Issue Date: | 2025-01-02 11:45:34 (UTC+8) |
| Abstract: | 綠色轉型將人們的關注從石油和天然氣轉向了礦物。這些原料對於生產電動車(EVs)、太陽能光電(PVs)和風力發電機等潔淨科技之技術至關重要。然而,這些原料的上游和下游生產早已被中國壟斷,且中國在過去十年中實施了越來越多的出口配額。為了減輕供應中斷的風險,歐盟委員會旨在透過「去風險化」來保護其經濟發展之所需,而這項目標在《關鍵原料法案》(CRMA)內的多項措施中得以體現,其中包括了設定國內礦物生產、加工,特別是回收的目標。此外,回收利用是屬於一個更為廣泛之經濟模式的一部分,即循環經濟,而循環經濟被認為具有潛力能降低國家和企業對初級原料的依賴。
因此,本研究聚焦於電動車之鋰電池的回收案例。本研究透過文本的分析,試圖回答以下兩個問題:「推動電動車鋰電池回收計畫的驅動因素是什麼?」以及「循環經濟能否成為增強歐盟電動車產業韌性的可持續戰略?」
研究結果顯示,儘管鋰電池原料的循環使用具有增強電動車產業韌性的潛力,其長期的可持續性將取決於外部因素,特別是政策支持。
The green transition has shifted the interest in oil and gas to minerals. Those elements are indeed essential for the production of clean technologies such as electric vehicles (EVs), photovoltaics (PVs), and wind turbines. The upstream and downstream production of these minerals has been monopolized by China, which in the last decade, has implemented a growing number of export quotas. To mitigate the risks of supply disruptions, the European Commission
aims at ‘de-risking’ its economy. This was, among others, illustrated by the Critical Raw Materials Act (CRMA) that includes targets for domestic production, processing, and most importantly recycling of minerals. Recycling is part of a broader economic model called a circular economy
which has the potential to reduce the reliance of national and sub-national actors on primary raw materials.
This research focuses on the case of EV lithium-ion battery recycling. Using document analysis, it aims to answer two questions: “What are the drivers behind EV lithium-ion battery recycling projects?” and “Can the circular economy be a sustainable strategy to enhance the
resilience of the electric vehicle industry in the European Union?”.
The analysis results show that although the circular use of LIB raw materials has the potential to enhance the resilience of the EV industry, its sustainable nature in the long term will be contingent on external elements, especially policy support. |
| Reference: | Albertsen, L., Richter, J. L., Peck, P., Dalhammar, C., & Plepys, A. (2021). Circular business
models for electric vehicle lithium-ion batteries: An analysis of current practices of vehicle
manufacturers and policies in the EU. Resources, Conservation and Recycling, 172, 105658.
Baars, J., Domenech, T., Bleischwitz, R., Melin, H. E., & Heidrich, O. (2021). Circular economy
strategies for electric vehicle batteries reduce reliance on raw materials. Nature
Sustainability, 4(1), 71-79.
Baranzelli, C., Blengini, G. A., Josa, S. O., & Lavalle, C. (2022). EU–Africa Strategic Corridors
and critical raw materials: two-way approach to regional development and security of
supply. International Journal of Mining, Reclamation and Environment, 36(9), 607-623.
Barteková, E., & Kemp, R. (2016). Critical raw material strategies in different world regions. The
United Nations University–Maastricht Economic and Social Research Institute on
Innovation and Technology (UNU-MERIT) Working Papers, 5.
Barteková, E., & Kemp, R. (2016). National strategies for securing a stable supply of rare earths in
different world regions. Resources Policy, 49, 153-164.
Bonviu, F. (2014). The European economy: From a linear to a circular economy. Romanian J. Eur.
Aff., 14, 78.
Carrara, S., Bobba, S., Blagoeva, D., Dias, P. A., Cavalli, A., Georgitzikis, K., Grohol, M., Itul, A.,
Kuzov, T., & Latunussa, C. E. (2023). Supply Chain Analysis and Material Demand
Forecast in Strategic Technologies and Sectors in the EU: A Foresight Study. Publications
Office of the European Union.
Charalampides, G., Vatalis, K. I., Apostoplos, B., & Ploutarch-Nikolas, B. (2015). Rare earth
elements: industrial applications and economic dependency of Europe. Procedia
Economics and Finance, 24, 126-135.
Charles, R. G., Douglas, P., Dowling, M., Liversage, G., & Davies, M. L. (2020). Towards
Increased Recovery of Critical Raw Materials from WEEE–evaluation of CRMs at a
component level and pre-processing methods for interface optimisation with recovery
processes. Resources, Conservation and Recycling, 161, 104923.
Chen, W.-M., Kim, H., & Yamaguchi, H. (2014). Renewable energy in eastern Asia: Renewable
energy policy review and comparative SWOT analysis for promoting renewable energy in
Japan, South Korea, and Taiwan. Energy Policy, 74, 319-329.
Cimprich, A., Young, S. B., Schrijvers, D., Ku, A. Y., Hagelüken, C., Christmann, P., Eggert, R.,
Habib, K., Hirohata, A., & Hurd, A. J. (2023). The role of industrial actors in the circular
economy for critical raw materials: a framework with case studies across a range of
industries. Mineral Economics, 36(2), 301-319.
Clean50. (2022). Li-Cyle Corp. Team. https://clean50.com/honourees/li-cycle-corp-2022/
Council, N. (2007). Report in Brief: Minerals, critical minerals and US economy. The National
Academy of Sciences, United States.
Cytera, C. (2023). Gallium, Germanium, and China — The Minerals Inflaming the Global Chip
War. Center for European Policy Analysis. https://cepa.org/article/china-gallium-and
germanium-the-minerals-inflaming-the-global-chip-war/
Desai, P. (2023). Cobalt supplies to swamp market, pressure prices further. Reuters.
https://www.reuters.com/markets/commodities/cobalt-supplies-swamp-market-pressure
prices-further-2023-03
07/#:~:text=LONDON%2C%20March%207%20(Reuters),demand%20is%20expected%2
0to%20rise.
Di Persio, F., Huisman, J., Bobba, S., Alves Dias, P., Blengini, G. A., & Blagoeva, D. (2020).
Information gap analysis for decision makers to move EU towards a Circular Economy for
the lithium-ion battery value chain. JRC121140. Publications Office of the European Union,
Luxembourg.
Doose, S., Mayer, J. K., Michalowski, P., & Kwade, A. (2021). Challenges in ecofriendly battery
recycling and closed material cycles: a perspective on future lithium battery generations.
Metals, 11(2), 291.
Drabik, E., & Rizos, V. (2018). Prospects for electric vehicle batteries in a circular economy. CEPS
Research Report No 2018/05, July 2018.
Ebner, J. (2014). Europe’s rare earth dependence on China: future perspectives. European Institute
for Asian Studies (Dec, EIAS Briefing Paper 2014, 07).
EEAS. (2022). EU-China Relations Factsheet
https://www.eeas.europa.eu/sites/default/files/documents/EU
China_Factsheet_01Apr2022.pdf
EIT-InnoEnergy. (2023). Energy Storage Mecaware Metal CApture for WAste REcycling.
https://www.innoenergy.com/discover-innovative-solutions/online-marketplace-for
energy-innovations/mecaware/
EIT. (2022). Launching the European Battery Academy to reskill thousands of industry workers
https://eit.europa.eu/news-events/news/launching-european-battery-academy-reskill
thousands-industry-workers
Ellen-Macarthur-Foundation. (2024). Circular economy introduction.
https://www.ellenmacarthurfoundation.org/topics/circular-economy
introduction/overview#:~:text=The%20circular%20economy%20is%20a,remanufacture%
2C%20recycling%2C%20and%20composting.
ELSA. The ELSA consortium: 10 partners - 5 EU countries. https://www.elsa
h2020.eu/Who_we_are.html
Emily Bensonand, T. D. (2023). China’s New Graphite Restrictions. Center for Strategic and
International Studies (CSIS). https://www.csis.org/analysis/chinas-new-graphite
restrictions#:~:text=As%20of%20December%201%2C%20Chinese,flake%20graphite%2
0and%20its%20products.%E2%80%9D
ERAMET. (2021). A website and great plans for the ReLieVe project
https://www.eramet.com/en/news/2021/04/a-website-and-great-plans-for-the-relieve
project/
ERAMET. (2023a). Eramet inaugurates a pilot plant for the recycling of electric vehicle batteries
https://www.eramet.com/en/news/2023/11/eramet-inaugurates-a-pilot-plant-for-the
recycling-of-electric-vehicle-batteries/
ERAMET. (2023b). Eramet looks into the future of black mass
https://www.eramet.com/en/news/2023/12/eramet-looks-into-the-future-of-black-mass/
ERAMET. (2024a). Eramet inaugurates a pilot plant for the recycling of electric
vehicle batteries https://www.eramet.com/wp-content/uploads/2023/11/2023-11-14-Eramet-PR
Demo-plant-inauguration.pdf
ERAMET. (2024b). Our actions for the planet and living beings.
https://www.eramet.com/en/commitments/environment/
ERAMET. (2024c). ReLieVe - Battery recycling. https://www.eramet.com/en/activities/relieve
battery-recycling/
EUR-Lex. (2008). Consolidated version of the Treaty on the Functioning of the European Union -
PART THREE: UNION POLICIES AND INTERNAL ACTIONS - TITLE VII:
COMMON RULES ON COMPETITION, TAXATION AND APPROXIMATION OF
LAWS - Chapter 1: Rules on competition - Section 2: Aids granted by States - Article 107
(ex
Article
87
TEC).
https://eur-lex.europa.eu/legal
content/EN/TXT/HTML/?uri=CELEX%3A12008E107#:~:text=Save%20as%20otherwise
%20provided%20in,trade%20between%20Member%20States%2C%20be
EUR-Lex. (2023). Regulation (EU) 2023/1542 of the European Parliament and of the Council of
12 July 2023 concerning batteries and waste batteries, amending Directive 2008/98/EC and
Regulation (EU) 2019/1020 and repealing Directive 2006/66/EC (Text with EEA
relevance). https://eur-lex.europa.eu/eli/reg/2023/1542/oj
European-Commission. (2018a). Annex to the Communication From the Commission to the
European Parliament, the Council, the European Economic and Social Committee and the
Committee of the Regions - Europe on the Move: Sustainable Mobility for Europe: safe,
connected and clean. https://eur-lex.europa.eu/resource.html?uri=cellar:0e8b694e-59b5
11e8-ab41
01aa75ed71a1.0003.02/DOC_3&format=PDF#:~:text=This%20Strategic%20Action%20
Plan%20combines,production%20and%20use%2C%20in%20the
European-Commission. (2018b). European Commission tackles barriers to innovation: the second
Innovation Deal focuses on batteries for electric vehicles. https://research-and
innovation.ec.europa.eu/news/all-research-and-innovation-news/european-commission
tackles-barriers-innovation-second-innovation-deal-focuses-batteries-electric-2018-03
12_en
European-Commission.
(2019). EU-China - A strategic outlook.
https://commission.europa.eu/system/files/2019-03/communication-eu-china-a-strategic
outlook.pdf
European-Commission. (2020). Communication from the Commission to the European Parliament,
the Council, the European Economic and Social Committee and the Committee of the
Regions - A new Circular Economy Action Plan for a cleaner and more competitive Europe.
https://eur-lex.europa.eu/legal
content/EN/TXT/?qid=1583933814386&uri=COM:2020:98:FIN
European-Commission. (2022a). INNOVATION FUND - ReLieve - Recycling Li-ion Batteries for
electric
Vehicles
12/if_pf_2022_relieve_en.pdf
European-Commission. (2022b).
https://climate.ec.europa.eu/system/files/2022
Signed
Innovation
Deals.
https://research-and
innovation.ec.europa.eu/law-and-regulations/ensuring-eu-legislation-supports
innovation/identifying-barriers/signed-deals_en
European-Commission. (2023a). Commission launches investigation on subsidised electric cars
from China https://ec.europa.eu/commission/presscorner/detail/en/ip_23_4752
European-Commission.
(2023b).
Critical
Raw
Materials.
https://single-market
economy.ec.europa.eu/sectors/raw-materials/areas-specific-interest/critical-raw
materials_en
European-Commission. (2023c). Critical Raw Materials Act. https://single-market
economy.ec.europa.eu/sectors/raw-materials/areas-specific-interest/critical-raw
materials/critical-raw-materials
act_en#:~:text=Overview%20of%20the%20Critical%20Raw%20Materials%20Act,
Critical%20raw%20materials&text=The%20European%20Critical%20Raw%20Materials
,chains%20for%20critical%20raw%20materials.
European-Commission. (2023d). End-of-Life Vehicles.
https://environment.ec.europa.eu/topics/waste-and-recycling/end-life-vehicles_en#law
European-Commission. (2023e). An EU approach to enhance economic security
https://ec.europa.eu/commission/presscorner/detail/en/IP_23_3358
European-Commission. (2023f). The Green Deal Industrial Plan - Putting Europe's net-zero
industry in the lead https://commission.europa.eu/strategy-and-policy/priorities-2019
2024/european-green-deal/green-deal-industrial-plan_en#paragraph_33968
European-Commission. (2023g). Horizon 2020 - Energy Local Storage Advanced system (ELSA).
https://cordis.europa.eu/project/id/646125
European-Commission. (2023h). The Net-Zero Industry Act: Accelerating the transition to climate
neutrality. https://single-market-economy.ec.europa.eu/industry/sustainability/net-zero
industry-act_en
European-Commission. (2024a). EU and Serbia sign strategic partnership on sustainable raw
materials, battery value chains and electric vehicles
https://ec.europa.eu/commission/presscorner/detail/en/ip_24_3922
European-Commission. (2024b). European Social Fund+. https://commission.europa.eu/funding
tenders/find-funding/eu-funding-programmes/european-social-fund_en
European-Commission. (2024c). Horizon Europe. https://research-and
innovation.ec.europa.eu/funding/funding-opportunities/funding-programmes-and-open
calls/horizon-europe_en
European-Commission. (2024d). Important Projects of Common European Interest (IPCEI).
https://competition-policy.ec.europa.eu/state-aid/ipcei_en
European-Commission. (2024e). Innovation Fund.
https://cinea.ec.europa.eu/programmes/innovation-fund_en
European-Commission. (2024f). Temporary Crisis and Transition Framework.
https://competition-policy.ec.europa.eu/state-aid/temporary-crisis-and-transition
framework_en
European-Council. (2022). Versailles Declaration
https://www.consilium.europa.eu/media/54773/20220311-versailles-declaration-en.pdf
European-Council. (2023). Council adopts new regulation on batteries and waste batter
https://www.consilium.europa.eu/en/press/press-releases/2023/07/10/council-adopts-new
regulation-on-batteries-and-waste-batteries/
European-Parliament-Council. (2018). Directive 2006/66/EC of the European Parliament and of
the Council of 6 September 2006 on batteries and accumulators and waste batteries and
accumulators and repealing Directive 91/157/EEC (Text with EEA relevance). https://eur
lex.europa.eu/legal-content/EN/TXT/?uri=celex%3A32006L0066
European-Parliament-Council. (2023). Regulation (EU) 2023/1542 of the European Parliament
and of the Council of 12 July 2023 concerning batteries and waste batteries, amending
Directive 2008/98/EC and Regulation (EU) 2019/1020 and repealing Directive
2006/66/EC (Text with EEA relevance). https://eur-lex.europa.eu/eli/reg/2023/1542/oj
European-Parliament. (2022). EU strategic autonomy 2013-2023: From concept to capacity.
https://www.europarl.europa.eu/thinktank/en/document/EPRS_BRI(2022)733589
European-Union. (2008). Consolidated version of the Treaty on the Functioning of the European
Union - PART ONE: PRINCIPLES - TITLE I: CATEGORIES AND AREAS OF UNION
COMPETENCE - Article 2. In.
(2024).
InvestEU
Fund.
https://investeu.europa.eu/investeu
European-Union.
programme/investeu-fund_en
Favot, M., & Massarutto, A. (2019). Rare-earth elements in the circular economy: The case of
yttrium. Journal of environmental management, 240, 504-510.
Gaines, L. (2014). The future of automotive lithium-ion battery recycling: Charting a sustainable
course. Sustainable Materials and Technologies, 1, 2-7.
Gaustad, G., Krystofik, M., Bustamante, M., & Badami, K. (2018). Circular economy strategies
for mitigating critical material supply issues. Resources, Conservation and Recycling, 135,
24-33.
Ghisellini, P., Cialani, C., & Ulgiati, S. (2016). A review on circular economy: the expected
transition to a balanced interplay of environmental and economic systems. Journal of
Cleaner Production, 114, 11-32.
Gleiss-Lutz.
(2024). PFAS Restriction Proposal on the EU Level.
https://www.gleisslutz.com/en/news-events/know-how/pfas-restriction-proposal-eu
level#:~:text=On%207%20February%202023%20the,present%20in%20many%20consu
mer%20goods.
Grilli, M. L., Bellezze, T., Gamsjäger, E., Rinaldi, A., Novak, P., Balos, S., Piticescu, R. R., &
Ruello, M. L. (2017). Solutions for critical raw materials under extreme conditions: A
review. Materials, 10(3), 285.
Helbig, C., Bradshaw, A. M., Wietschel, L., Thorenz, A., & Tuma, A. (2018). Supply risks
associated with lithium-ion battery materials. Journal of Cleaner Production, 172, 274-286.
Hool, A., Helbig, C., & Wierink, G. (2023). Challenges and opportunities of the European Critical
Raw Materials Act. Mineral Economics, 1-8.
Hool, A., Schrijvers, D., van Nielen, S., Clifton, A., Ganzeboom, S., Hagelueken, C., Harada, Y.,
Kim, H., Y. Ku, A., & Meese-Marktscheffel, J. (2022). How companies improve critical
raw material circularity: 5 use cases: Findings from the International Round Table on
Materials Criticality. Mineral Economics, 35(2), 325-335.
IEA. (2023). France - What is the role of energy transformation in France?
https://www.iea.org/countries/france/energy-mix
IER. (2022). China Expected to Increase Control Over Global Lithium and Cobalt Supply. Institute
for
Energy
Research.
manager/articles/
International-Energy-Agency.
https://www.instituteforenergyresearch.org/about/ier-site
(2024).
Outlouk for battery and energy demand.
https://www.iea.org/reports/global-ev-outlook-2024/outlook-for-battery-and-energy
demand
Johansson, N. (2021). Does the EU’s action plan for a circular economy challenge the linear
economy? Environmental science & technology, 55(22), 15001-15003.
Kastanaki, E., & Giannis, A. (2023). Dynamic estimation of end-of-life electric vehicle batteries
in the EU-27 considering reuse, remanufacturing and recycling options. Journal of Cleaner
Production, 393, 136349.
Kirchherr, J., Reike, D., & Hekkert, M. (2017). Conceptualizing the circular economy: An analysis
of 114 definitions. Resources, Conservation and Recycling, 127, 221-232.
Lander, L., Cleaver, T., Rajaeifar, M. A., Nguyen-Tien, V., Elliott, R. J., Heidrich, O., Kendrick,
E., Edge, J. S., & Offer, G. (2021). Financial viability of electric vehicle lithium-ion battery
recycling. Iscience, 24(7).
Lanzolla, F. F. S. a. G. (2005). The Half-Truth of First-Mover Advantage. Harvard Business
Review. https://hbr.org/2005/04/the-half-truth-of-first-mover-advantage
LARA, H. (2018). Recyclage des batteries : notre visite au cœur d’une usine française. Automobile
Propre.
https://www.automobile-propre.com/recyclage-des-batteries-notre-visite-au
coeur-dune-usine
francaise/#:~:text=La%20SNAM%20affirme%20y%20traiter,%C3%A0%206000%20eur
os%20la%20tonne.
Leal, V., Ribeiro, J., Coelho, E., & Freitas, M. (2023). Recycling of spent lithium-ion batteries as
a sustainable solution to obtain raw materials for different applications. Journal of Energy
Chemistry, 79, 118-134.
Leprince-Ringuet, D. (2023). Battery recycling startup Mecaware raises €40m Series A. sifted.
https://sifted.eu/articles/mecaware-battery-recycling-series-a-news
Lewandowski, M. (2016). Designing the business models for circular economy—Towards the
conceptual framework. Sustainability, 8(1), 43.
Lewicka, E., Guzik, K., & Galos, K. (2021). On the possibilities of critical raw materials production
from the EU’s primary sources. Resources, 10(5), 50.
Li-Cycle. (2022). Sustainability at Li-Cycle.
Li-Cycle. (2023a). 2023 Sustainability Report.
https://li-cycle.com/wp
content/uploads/2024/05/2023-Li-Cycle-Sustainability-Report.pdf
Li-Cycle. (2023b). Li-Cycle and KION Group Form Strategic Global Lithium-Ion Battery
Recycling Partnership; Li-Cycle Announces New Spoke Development in France https://li
cycle.com/press-releases/li-cycle-and-kion-group-form-strategic-global-partnership/
Li-Cycle. (2024a). Delivering value through recovered materials and process innovation. https://li
cycle.com/products/
Li-Cycle. (2024b). Doing our part for a cleaner planet. https://li-cycle.com/sustainability/
Li-Cycle. (2024c). Innovative, safe, scalable, and sustainable process to recover critical materials
from all types of lithium-ion batteries. https://li-cycle.com/technology/
Li-Cycle. (2024d). Lithium-ion battery recycling. https://li-cycle.com/
Månberger, A. (2023). Critical raw material supply matters and the potential of the circular
economy to contribute to security. Intereconomics, 58(2), 74-78.
Mancheri, N. A. (2015). World trade in rare earths, Chinese export restrictions, and implications.
Resources Policy, 46, 262-271.
Mathieux, F., Ardente, F., Bobba, S., Nuss, P., Blengini, G. A., Dias, P. A., Blagoeva, D., De Matos,
C. T., Wittmer, D., & Pavel, C. (2017). Critical raw materials and the circular economy.
Publications Office of the European Union: Bruxelles, Belgium.
Matos, C. T., Mathieux, F., Ciacci, L., Lundhaug, M. C., León, M. F. G., Müller, D. B., Dewulf,
J., Georgitzikis, K., & Huisman, J. (2022). Material system analysis: a novel multilayer
system approach to correlate EU flows and stocks of Li‐ion batteries and their raw materials.
Journal of Industrial Ecology, 26(4), 1261-1276.
Mayyas, A., Steward, D., & Mann, M. (2019). The case for recycling: Overview and challenges in
the material supply chain for automotive li-ion batteries. Sustainable Materials and
Technologies, 19, e00087.
Mecaware. (2023a). GREENTECH: MECAWARE SECURES €40M TO BECOME THE LEADER
IN BATTERY RECYCLING AND THE PRODUCTION OF STRATEGIC METALS IN
FRANCE AND EUROPE https://mecaware.com/latest-news/greentech-mecaware-secures
e40m-to-become-the-leader-in-battery-recycling-and-the-production-of-strategic-metals
in-france-and-europe/
Mecaware. (2023b). Greentech: Une étape réussie dans la création d'un nouvel écosystème en
Hauts-de-France pour le recyclage des battéries. https://mecaware.com/latest
news/greentech-une-etape-reussie-dans-la-creation-dun-nouvel-ecosysteme-en-hauts-de
france-pour-le-recyclage-des-batteries/
MTE. (2023a). France 2030 : annonce des lauréats "recyclage des batteries" de l'appel à projets
"recyclage, recyclabilité et réincorporation des matériaux"
https://www.ecologie.gouv.fr/presse/france-2030-annonce-laureats-recyclage-batteries
lappel-projets-recyclage-recyclabilite
MTE. (2023b). France 2030 : le Gouvernement dévoile les 5 premiers lauréats de l'appel à projets
"métaux critiques". https://www.ecologie.gouv.fr/presse/france-2030-gouvernement
devoile-5-premiers-laureats-lappel-projets-metaux-critiques
Natarajan, S., Divya, M. L., & Aravindan, V. (2022). Should we recycle the graphite from spent
lithium-ion batteries? The untold story of graphite with the importance of recycling.
Journal of Energy Chemistry, 71, 351-369.
Olivetti, E. A., Ceder, G., Gaustad, G. G., & Fu, X. (2017). Lithium-ion battery supply chain
considerations: analysis of potential bottlenecks in critical metals. Joule, 1(2), 229-243.
Orano. (2021). CIME, a new pilot facility in Europe. In.
Orano. (2022). Orano invests in recycling of electric vehicle batteries.
https://www.orano.group/en/nuclear-expertise/valuation-of-strategic-metals/recycling-of
electric-vehicle-batteries-launch-of-a-new-industrial-pilot
Orano. (2023). Orano commissions its industrial pilots for the recycling of electric vehicle batteries
https://www.orano.group/en/news/news-group/2023/november/orano-commissions-its
industrial-pilots-for-the-recycling-of-electric-vehicle-batteries
Öztürk, M., Evin, E., Özkan, A., & Banar, M. (2023). Comparison of waste lithium-ion batteries
recycling methods by different decision making techniques. Environmental Research and
Technology, 6(3), 226-241.
Pagliaro, M., & Meneguzzo, F. (2019). Lithium battery reusing and recycling: A circular economy
insight. Heliyon, 5(6).
Parliament, E. (2023). Amendments adopted by the European Parliament on 14 September 2023 on the
proposal for a regulation of the European Parliament and of the Council establishing a
framework for ensuring a secure and sustainable supply of critical raw materials.
Paschal, C. (2022). Mecaware transforme les batteries en fin de vie en une mine de métaux. L'Usine Nouvelle.
https://www.usinenouvelle.com/article/mecaware-transforme-les-batteries
enfin-de-vie-en-une-mine-de-metaux.N2018852
Pavel, C. C., Marmier, A., Alves Dias, P., Blagoeva, D., Tzimas, E., Schüler, D., Schleicher, T.,
Jenseit, W., Degreif, S., & Buchert, M. (2016). Substitution of critical raw materials in low
carbon technologies: lighting, wind turbines and electric vehicles. Luxembourg: European
Commission, Oko-Institut eV.
PH.B. (2015). Snam étend son partenariat avec PSA Peugeot Citroën. Centre Presse.
https://www.centrepresseaveyron.fr/2015/12/09/snam-etend-son-partenariat-avec-psa
peugeot-citroen,3978960.php
Rabe, W., Kostka, G., & Stegen, K. S. (2017). China's supply of critical raw materials: Risks for
Europe's solar and wind industries? Energy Policy, 101, 692-699.
Rensmo, A., Savvidou, E. K., Cousins, I. T., Hu, X., Schellenberger, S., & Benskin, J. P. (2023).
Lithium-ion battery recycling: a source of per-and polyfluoroalkyl substances (PFAS) to
the environment? Environmental Science: Processes & Impacts, 25(6), 1015-1030.
Reynolds, M., & Goodman, M. P. (2022). China’s Economic Coercion: Lessons from Lithuania.
Washington DC: Center for Strategic and International Studies (CSIS), 6.
RMIS. (2023a). Raw Materials Profiles - Cobalt. https://rmis.jrc.ec.europa.eu/rmp/Cobalt
RMIS. (2023b). Raw Materials Profiles - Lithium. https://rmis.jrc.ec.europa.eu/rmp/Lithium
RMIS. (2023c). Raw Materials Profiles - Natural Graphite.
https://rmis.jrc.ec.europa.eu/rmp/Natural%20Graphite
RMIS. (2023d). Raw Materials Profiles - Nickel https://rmis.jrc.ec.europa.eu/rmp/Nickel
Rönkkö, P., Majava, J., Hyvärinen, T., Oksanen, I., Tervonen, P., & Lassi, U. (2023). The circular
economy of electric vehicle batteries: a Finnish case study. Environment Systems and
Decisions, 1-14.
Schmid, M. (2019). Mitigating supply risks through involvement in rare earth projects: Japan's
strategies and what the US can learn. Resources Policy, 63, 101457.
Schmid, M. (2020). Challenges to the European automotive industry in securing critical raw
materials for electric mobility: the case of rare earths. Mineralogical Magazine, 84(1), 5
17. (2023).
Scott, S., & Ireland, R. (2020). Lithium-Ion battery materials for electric vehicles and their global
value chains. Office of Industries, US International Trade Commission.
SK-tes. TES Prepares to Open New Battery Recycling Facilities
https://www.sktes.com/press-release/tes-prepares-to-open-new-battery-recycling-facilities
SK-tes. (2024). Sustainable Battery Solutions. https://www.sktes.com/it-services/commercial
battery-recycling
Smol, M., Marcinek, P., & Koda, E. (2021). Drivers and barriers for a circular economy (CE)
implementation in Poland—A case study of raw materials recovery sector. Energies, 14(8),
2219.
SNAM. (2023). For the fourth year running, SNAM has renewed its EcoVadis Silver Medal!
https://www.snam.com/en/for-the-fourth-year-running-snam-has-renewed-its-ecovadis
silver-medal/
SNAM. (2024a). Nos engagements. https://www.snam.com/engagements/
SNAM. (2024b). Recyclage. https://www.snam.com/recyclage/
Song, J., Yan, W., Cao, H., Song, Q., Ding, H., Lv, Z., Zhang, Y., & Sun, Z. (2019). Material flow
analysis on critical raw materials of lithium-ion batteries in China. Journal of Cleaner
Production, 215, 570-581.
Theodosopoulos, V. (2020). The Geopolitics of Supply: towards a new EU approach to the security
of supply of critical raw materials? Institute for European Studies Policy Brief.
Tiess, G. (2010). Minerals policy in Europe: Some recent developments. Resources Policy, 35(3),
190-198.
aux
Tobelem, B. (2023). Batterie, énergie solaire, cybersécurité… Des “académies européennes” pour former métiers des technologies d’avenir.
Toute l'Europe.
https://www.touteleurope.eu/economie-et-social/batterie-energie-solaire-cybersecurite
des-academies-europeennes-pour-former-aux-metiers-des-technologies-d-avenir/
Trafton, A. (2024). Cobalt-free batteries could power cars of the future. MIT News on campus and
around the world. https://news.mit.edu/2024/cobalt-free-batteries-could-power-future
cars-0118
USGS. (2022). Lithium. https://pubs.usgs.gov/periodicals/mcs2022/mcs2022-lithium.pdf
USGS. (2023). Graphite (Natural). https://pubs.usgs.gov/periodicals/mcs2023/mcs2023
graphite.pdf
USGS. (2024). Nickel. https://pubs.usgs.gov/periodicals/mcs2024/mcs2024-nickel.pdf
Veolia. (2020a). Electric cars: batteries of the future will be recycled
https://www.veolia.com/en/planetlive/electric-cars-batteries-future-will-be-recycled
Veolia. (2020b). Solvay and Veolia partner to recycle electric vehicle batteries
https://www.veolia.com/en/news/recycling-lithium-ion-batteries-electric-vehicles-solvay
veolia
Veolia. (2021a). Movin'On Summit: the Veolia, Groupe Renault and Solvay alliance at the service
of the circular economy for sustainable mobility batteries
https://www.veolia.cn/en/news/movinon-summit-veolia-groupe-renault-and-solvay
alliance-service-circular-economy-sustainable
Veolia. (2021b). Recycling electric vehicle batteries: ecological transformation and preserving
resources (The Veolia Institute Review, Issue.
https://www.institut.veolia.org/sites/g/files/dvc2551/files/document/2021/11/74%20Recyc
ling%20electric%20vehicle.pdf
Veolia. (2021c). Veolia, Groupe Renault and Solvay join forces to recycle end-of-life EV battery
metals in a closed loop https://www.veolia.com/en/news/recycling-electric-vehicles
batteries-solvay-renault-veolia
Veolia. (2022). Li-ion battery recycling. https://www.weloop.org/wp
content/uploads/2022/07/WeLoop-Workshop-Li-Ion-Battery-recycling-with-VEOLIA.pdf
Veolia. (2023). Développer des solutions circulaires et sûres pour la fin de vie des batteries
lithium-ion
https://www.veolia.com/sites/g/files/dvc4206/files/document/2023/07/recyclage-batteries
lithium-ion-2023.pdf
Veolia. (2024a). Développer des solutions circulaires et sûres pour la fin de vie des batteries
lithium-ion. https://www.veolia.com/sites/g/files/dvc4206/files/document/2024/06/veolia
recyclage-batteries-lithium-ion-2024.pdf
Veolia. (2024b). PFAS Technology, Remediation and Treatment.
https://www.watertechnologies.com/applications/pfas-remediation
Veolia. (2024c). Recycling electric car batteries. https://www.veolia.com/en/pollution/hazardous
waste/recycling-electric-car-batteries
Volkswagen. (2021). Battery recycling pilot plant https://www.volkswagen
group.com/en/images/detail/battery-recycling-pilot-plant-35568
Wadsworth, T. (2023). Li-Cycle - Providing a Closed-Loop Solution for Battery Recycling.
https://batterytechassociation.org/wp-content/uploads/2023/12/1130-Hall-2-Tom
Wadsworth-Li-Cycle-2.pdf
Wrålsen, B., Prieto-Sandoval, V., Mejia-Villa, A., O'Born, R., Hellström, M., & Faessler, B. (2021).
Circular business models for lithium-ion batteries-Stakeholders, barriers, and drivers.
Journal of Cleaner Production, 317, 128393.
WTO. (2013a). DS394: China — Measures Related to the Exportation of Various Raw Materials.
WTO. https://www.wto.org/english/tratop_e/dispu_e/cases_e/ds394_e.htm
WTO. (2013b). DS395: China — Measures Related to the Exportation of Various Raw Materials.
WTO. https://www.wto.org/english/tratop_e/dispu_e/cases_e/ds395_e.htm
WTO. (2013c). DS398: China — Measures Related to the Exportation of Various Raw Materials.
https://www.wto.org/english/tratop_e/dispu_e/cases_e/ds398_e.htm
Wübbeke, J. (2013). Rare earth elements in China: Policies and narratives of reinventing an
industry. Resources Policy, 38(3), 384-394.
Zanoletti, A., Carena, E., Ferrara, C., & Bontempi, E. (2024). A Review of Lithium-Ion Battery
Recycling: Technologies, Sustainability, and Open Issues. Batteries, 10(1), 38.
Ziemann, S., Müller, D. B., Schebek, L., & Weil, M. (2018). Modeling the potential impact of
lithium recycling from EV batteries on lithium demand: A dynamic MFA approach.
Resources, Conservation and Recycling, 133, 76-85.
中华人民共和国国土资源部. (2008). 全国矿产资源规划(2008~2015 年)
https://www.cnmn.com.cn/ShowNews1.aspx?id=282722&page=6 |
| Description: | 碩士
國立政治大學
國際研究英語碩士學位學程(IMPIS)
111862018 |
| Source URI: | http://thesis.lib.nccu.edu.tw/record/#G0111862018 |
| Data Type: | thesis |
| Appears in Collections: | [國際研究英語碩士學位學程] 學位論文
|
Files in This Item:
| File |
Description |
Size | Format | |
|---|
| 201801.pdf | | 1522Kb | Adobe PDF | 0 | View/Open |
|
All items in 政大典藏 are protected by copyright, with all rights reserved.
|
