Lithium-ion Battery Recycling Market
By Battery Chemistry (Lithium-Iron Phosphate, Lithium-Manganese Oxide, Lithium-Nickel-Cobalt-Aluminum Oxide, Lithium-Nickel-Manganese Cobalt, Lithium-Titanate Oxide),
By End Use (Automotive, Industrial, Consumer Electronics),
By Recycling Process (Hydrometallurgical Process, Physical/Mechanical Process, Pyrometallurgy Process),
By Region (North America, Europe, Asia-Pacific, Latin America, Middle East & Africa):
Global Analysis and Forecast 2023-2033
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The global lithium-ion battery recycling market showcased a revenue of USD 3.9 billion in 2022 and is projected to witness a compounded annual growth rate (CAGR) of more than 21.14% over the forecast period of 2023-2033.
Russia-Ukraine War Impact
Market Scope
About the Market
Impact of COVID-19
Global Economic Slowdown
Market Dynamics
Driver
Restrain
Opportunity
Recent Developments
Synopsis
How is this report helpful
FAQ's
Report Coverage
Related Reports
Lithium-ion batteries have become a critical part of the energy supply chain for transportation (in electric vehicles) and renewable energy storage systems. Recycling is considered one of the most effective ways to recover the materials for spent lithium-ion battery streams and circulate the material in the critical supply chain. According to reports, the revenue generated by retailing these recovered metals or elements, whether that goes into supplementary battery recycling or other second usage requests, and most metals recovered go into battery manufacturing only for the second use of batteries in low-power applications. Government regulations, the need for green infrastructure, and growing environmental awareness will fuel the market growth of lithium-ion batteries.
As per the analysis of Bloomberg, lithium-ion battery pack prices fell from $1,100 per kilowatt-hour in 2010 to $137/kWh in 2020, witnessing a decline of 89% in real terms. Moreover, by 2023, average prices will be nearly $100/kWh as per the latest forecast. This is accredited to growing competition in the lithium-ion battery market coupled with innovations in the automotive industry. Moreover, many companies are taking initiatives to build a zero-waste policy in the coming years. For instance, in May 2021, Ultium Cells LLC, a joint venture between General Motors and LG Energy Solution, signed an agreement with Li-Cycle to recycle up to 100 percent of the material scrap from battery cell manufacturing. This contract is a part of General Motors' zero-waste initiative that aims to sidetrack more than 90 percent of its manufacturing waste from landfills and incineration globally by 2025. Along with companies, national governments are also chipping in zero waste policies to mitigate environmental degradation. For instance, in April 2019, the Scottish government declared a global climate emergency. It planned to reach net zero by 2045, with short-term targets of 75% by 2030 and 90% by 2040. The major players and governments all around the globe implementing favorable policies, along with rising demand from the automotive industry, are creating market opportunities for the lithium-ion battery recycling market.
Asian companies are governing the market for electric vehicle batteries since nine out of the top ten producers are Asian companies despite countries such as Europe and the U.S. making efforts to dominate the market. As of 2022, the Chinese firms hold control of 56% of the global market for electric vehicle batteries, tailed by Korean and Japanese producers with 26% and 10%, respectively. Chinese companies supply Lithium-ion batteries to renowned automobile manufacturers such as Tesla, BMW, and Toyota. China has the largest fleet of electric cars, with 4.5 million units, followed by Europe, with 3.2 million units. The governments in the Asia-Pacific region are increasing the adoption of electric vehicles in the form of tax exemptions, discounts, and no-tolls for EVs. For instance, in July 2019, the goods and service tax (GST) was reduced by the Indian government on e-vehicles from 12% to 5% and on chargers or charging stations for EVs from 18% to 5%. Government initiatives such as these will propel the market demand for electric vehicles, which will create market opportunities for the lithium-ion recycling market in the forecast period.
Impact of Russia-Ukraine War on Lithium-ion Battery Recycling Market
There is a direct impact of the Russia-Ukraine war on the global lithium-ion battery recycling market. However, the European region will witness the highest impact. Increased trade sanctions across the European region, followed by disruption in global trade routes, are one of the major factors imposed due to war and limiting business opportunities. Factors such as lack of raw materials, limited manufacturing capabilities in the European region, and withdrawal of major lithium-ion battery recycling manufacturers from Russia and Ukraine, creating a demand gap indirectly impacting the inflation within the region, are among other factors poised to hinder the business opportunities. The effects of the conflict on the upstream supply chain of crucial minerals necessary for the production of lithium-ion batteries and semiconductors was yet another strike to the industry. The extent of the risks threatening the supply chain in the environment was exposed by the staggering news that nickel prices had reached $100,000 per ton and had triggered the London Metal Exchange (LME) to stall in March 2022. With disruptions in supply chains for the production of lithium-ion batteries, the recycling sector of these batteries took a hit during the crisis. Though the impact was short-term, the market is recovering well.
Lithium-ion Battery Recycling: Market Scope
The Lithium-ion battery recycling market is divided into three segments battery chemistry, end use, and recycling process. Furthermore, these segments are subdivided into respective categories and cross-referenced to North America, Europe, Asia-Pacific, Latin America, and Middle East & Africa for regional analysis. The battery chemistry segment is further categorized into lithium-iron phosphate, lithium-manganese oxide, lithium-nickel-cobalt-aluminum oxide, lithium-nickel-manganese cobalt, and lithium-titanate oxide. The end-user segment is segregated into automotive, industrial, and consumer electronics. The recycling process segment of the Lithium-ion battery remarket is bifurcated, and pyrometallurgy processes, physical/mechanical process, and pyrometallurgy process. Each of these segments is further classified into regions: North America, Europe, Asia-Pacific, Latin America, and Middle East & Africa. The historical dataset of 2018-2022 is provided in the report, whereas the forecast period of 2023-2033 is offered.
Lithium-Nickel-Manganese Cobalt will witness the highest growth rate within the Battery chemistry segment
Lithium-nickel-manganese cobalt shows a fulfilling revenue generation in the chemistry type segment owing to characteristics that provide higher battery life, higher temperature handling durability, and long-term reliability. Ternary cathode materials (NMC) in lithium-ion batteries have nickel, manganese, and cobalt as their primary components, and as the cathode materials for lithium-ion secondary batteries, are used mainly in batteries aimed at electrically-powered cars, including hybrid vehicles. According to reports, most Li-manganese batteries fuse with lithium nickel manganese cobalt (NMC) to improve the definite energy and lengthen the life span. This amalgamation brings out the best in each system, and the LMO (NMC) is preferred for most electric vehicles, such as the Nissan Leaf, Chevy Volt, and BMW i3. The LMO part of the battery, which can be about 30 percent, provides a high current boost on acceleration, while the NMC part gives a long driving range. Li-ion research gravitates heavily towards combining Li-manganese with cobalt, nickel, manganese, and/or aluminum as active cathode material. These three active metals and the silicon enhancement can conveniently be chosen to enhance the specific energy (capacity), specific power (load capability), or longevity. While consumer batteries go for high capacity, industrial applications require battery systems with good loading capabilities that deliver long life and provide safe and dependable service.
The automotive segment will capture the highest market share between 2023-2033
It is observed that the automotive segment would be capturing a higher market share in the end-user sector. This observation is accredited to the falling prices of lithium-ion batteries which cut down the cost of electric vehicles. As per the analysis of Bloomberg, lithium-ion battery pack prices fell from $1,100 per kilowatt-hour in 2010 to $137/kWh in 2020, witnessing a decline of 89% in real terms. Moreover, by 2023, average prices will be nearly $100/kWh as per the latest forecast. Global electric car registrations increased by 70% in 2020 despite the Covid-19 pandemic, reaching a record 4.6% market share. China has the largest fleet of electric cars, with 4.5 million units, followed by Europe, with 3.2 million units. The demand for electric vehicle batteries poses challenges for the battery supply chain, which needs to secure sufficient raw materials such as lithium, nickel, cobalt, and manganese; scale up production capacity through building gigafactories; and ensure environmental and social sustainability along the value chain23. The electric vehicle battery market offers significant value-creation opportunities for manufacturers, suppliers, and service providers along the value chain. A new battery-manufacturing plant with a total capacity of 30 to 40 GWh per year could directly create as many as 3,200 jobs and generate significant growth in GDP. Moreover, battery manufacturing could also support other related industries such as mining, recycling, charging infrastructure, etc., creating an ecosystem of innovation and collaboration. The pace with which the demand for lithium-ion batteries is increasing by the automotive industry will foster the growth of the lithium-ion recycling market.
Hydrometallurgical process segment within the recycling process to witness the highest CAGR during the forecast timeframe
The forecast timeframe has predicted proliferation in the use of hydrometallurgical processes for recycling lithium-ion batteries. This is primarily because the material's physical properties in the LIB suits the process. The energy consumption during the process is also incredibly low since it involves leaching and reduction. It is typically divided into acid leaching and biological leaching according to the leaching method. The acid-leaching process has a recovery rate of over 99% for Co and Li and a recovery rate of over 98% for Cu. The recovery rate of hydrometallurgy is far from that of pyrometallurgy. In the acid leaching of electrode materials, inorganic acids are mostly used, usually including hydrochloric acid (HCl), sulfuric acid (H2SO4), nitric acid (HNO3), and phosphoric acid (H3PO4). In contrast, the organic acids studied include citric acid, oxalic acid, and tartaric acid. The hydrometallurgical process's efficiency and ease make it the most preferred recycling process.
Asia-Pacific to witness the highest growth rate during the forecast period.
Asia-pacific region is promising a dynamic rise in disposable income, which is then expected to trigger the growth of the electric vehicle market, which in return will increase the market consumption of lithium-ion battery recycling. Asian companies are governing the market for electric vehicle batteries since nine out of the top ten producers are Asian companies despite countries such as Europe and the U.S. making efforts to dominate the market. As of 2022, the Chinese firms hold control of 56% of the global market for electric vehicle batteries, tailed by Korean and Japanese producers with 26% and 10%, respectively. Chinese companies supply Lithium-ion batteries to renowned automobile manufacturers such as Tesla, BMW, and Toyota. China has the largest fleet of electric cars, with 4.5 million units, followed by Europe, with 3.2 million units. The governments in the Asia-Pacific region are increasing the adoption of electric vehicles in the form of tax exemptions, discounts, and no-tolls for EVs. India has set a target of EV sales penetration of 30% of private cars, 70% of commercial cars, 40% of buses, and 80% of two and three-wheelers by 2030. In absolute numbers, these would amount to having eight crore electric vehicles on the road by 2030. Moreover, countries becoming self-sufficient in the region are propelling the demand for recycling lithium-ion in this region. For instance, in February 2023, the Geological Survey of India discovered an 'inferred' reserve of 5.9 million tonnes of Lithium in Jammu & Kashmir. This discovery is likely to make India self-sufficient in the electric vehicle battery market and aid the country in becoming an emerging manufacturer. Advancements such as these in the Asia-Pacific region are fostering the demand for the lithium-ion battery recycling market.
Impact of COVID-19 on Lithium-ion Battery Recycling Market
COVID-19 significantly impacted the lithium-ion battery recycling market in terms of heavy losses and dropped sales on the commercial front. This is largely attributed to the blocking of distribution channels. Lithium-ion battery recycling manufacturing ceased to exceptionally low levels and did not witness even minimal distribution or revenue generation. COVID-19 also created a demand for green transportation keeping the environment in mind, which will boost the growth of the EV market in the long term, directly affecting the lithium-ion battery recycling market. Global electric car registrations increased by 70% in 2020 despite the Covid-19 pandemic, reaching a record 4.6% market share. The need for transportation decreased significantly during the pandemic, which had a short-term adverse effect on the market. However, in the long term, there should not be any problems when it comes to global market growth.
Lithium-ion Battery Recycling: Market Dynamics
The market dynamics section of the report covers a depth analysis of drivers, restraints, and opportunities impacting the Lithium-ion battery recycling market. The report also encompasses major market strategies practiced by the industry, followed by patent analysis, product analysis, competitive benchmarking of companies, PORTER and PESTLE analysis of the Lithium-ion battery recycling industry, pricing analysis, and geographic competitiveness to provide a detailed understanding. The major players operating the market are Fortum, Glencore International AG, International Metals Reclamation Company, Neometals Ltd, OnTo Technologies LLC, Raw Materials Company Inc. (RMC), Redwood Materials Inc., Recupyl Sas, Retriev Technologies Inc., and Umicore. These companies cumulatively hold the majority of the Lithium-ion battery recycling market share and actively undergo strategic development such as new product launches, mergers, collaborations, business expansions, acquisitions, and long-term contracts to ensure market penetration. These companies also largely focus on research and development to gain competitiveness in the market. A detailed analysis of these companies is offered in the report.
Driver: Increasing demand for electric vehicles increasing consumption of lithium-ion batteries boosting market growth for recycling
The increasing market Demand for lithium-ion battery recycling is a collective outcome of the growing demand for electric vehicles. Its quick recharge capabilities and high energy density make the battery suitable for use in EVs. The only technology on the market that satisfies Original Equipment Manufacturer (OEM) specifications for electric cars with enough range and quick recharge. Manufacturers are largely using lithium-ion batteries to power PHEVs and battery electric vehicles (BEVs) compared to Nickel Metal Hydride (NiMH) batteries used in initial hybrid cars. Lithium-ion batteries accounted for over 90% of BEV battery capacity deployed worldwide in 2020, as per a report. Moreover, the worldwide production capacity for lithium-ion batteries for electric vehicles also increased from 98 GWh in 2017 to 516 GWh in 2020. Moreover, national governments are trying to increase electric vehicle adoption. For instance, in October 2022, the German government approved a plan to spend 6.3 billion euros ($6.1 billion) till 2025 to swiftly scale up the figure of charging stations for electric vehicles across the country. The plan foresees a 14-fold surge in the number of charging stations, climbing to 1 million by 2030 from around 70,000 in 2022. The rapid growth of the electric vehicles market will fuel the market growth of the lithium-ion battery recycling market.
Restrain: Supply chain threat to hinder lithium-ion battery demand hindering the recycling market
With the increase in demand for EVs, the demand for lithium-ion batteries has also increased. Lithium-ion battery manufacturers must meet the demand for these batteries. The production of EV batteries is concentrated in certain regions, with a few large companies dominating the market. This increases the threat of supply chain breaking because any disruption in production in these companies can adversely affect the entire market. The supply chain in this industry, along with being concentrated, is complex as well. Many components and raw materials are scarce and subject to geopolitical risk. Graphite is utilized as the anode material in lithium-ion batteries. Graphite contributes largely to the cost of making cells. China has dominated the whole supply chain of graphite for many years and produces 70% of the flake graphite, which necessitates being treated before being used in batteries, and around 50% of the synthetic graphite utilized in the batteries. Supply chains threatening the growth of the lithium-ion batteries market will reduce the prospect of these batteries getting recycled.
Opportunity: Decreasing prices of lithium-ion batteries to increase demand in the power industry, creating market demand for recycling
The Lithium-ion battery recycling market shows promising opportunities in the Asia-Pacific region and developing countries of other regions. This is largely observed due to decreasing prices of lithium-ion batteries. As per the analysis of Bloomberg, lithium-ion battery pack prices fell from $1,100 per kilowatt-hour in 2010 to $137/kWh in 2020, witnessing a decline of 89% in real terms. Moreover, by 2023, average prices will be nearly $100/kWh as per the latest forecast. This is accredited to growing competition in the lithium-ion battery market coupled with innovations in the automotive industry. The lithium-ion battery will therefore witness high demand and will be used in several applications interrelated to the power sectors, such as energy storage systems and others, which in return will probably initiate the market in the power sector. Higher application and use of lithium-ion batteries by different sectors will result in higher demand for recycling of lithium-ion batteries.
Lithium-Ion Battery Recycling Market: Recent Developments
- In March 2023, Green Li-ion, a Singapore-based lithium-ion battery recycling technology player, secured $20.5 million in its pre-series B funding round. The investors included venture capital firm TRIREC, solar firm Banpu NEXT, and energy company Equinor Ventures. Through this funding, Green Li-ion has developed a prototype of its GLMC technology that can process 4-6 metric tons of discarded batteries on a daily basis which is equal to recycling more than 20 electric vehicle batteries or 70,000 smartphone batteries.
- In August 2021, Li-Cycle Holdings Corp, the leading lithium-ion battery recycler in North America, combined its business with Peridot Acquisition Corp. This merger represents a combined company pro forma equity value of $1.55 billion. This merger is a part of Li-cycle's attempt to close the battery supply chain loop. This merger has provided Li-cycle with the capital to exploit momentous growth opportunities, develop their revolutionising commercial technology, and build lithium-ion recycling facilities across the globe.
- In July 2021, Redwood Materials raised $700M to expand its battery recycling operation as a part of Series C funding. The Series C was led and advised by T. Rowe Price Associates and Goldman Sachs Asset Management, Baillie Gifford, Canada Pension Plan Investment Board, and Fidelity. Through this funding, Redwood Materials aims to develop its prevailing well beyond its Carson City, Nevastudy da, home base to locations all over North America and even in Europe.
Lithium-ion Battery Recycling Market: Synopsis
The study of the Lithium-ion battery recycling market offers revenue and growth data sets of segments that are provided at the global level, regional level, and country levels. The historical data set of 2018-2022 is offered in the report, along with the forecast period of 2023-2033. For the purpose of analysis, Quadrant Market Insights (QMI) has segregated the Lithium-ion battery recycling market into three major segments as follows:
By Battery Chemistry
- Lithium-Iron Phosphate
- Lithium-Manganese Oxide
- Lithium-Nickel-Cobalt-Aluminum Oxide
- Lithium-Nickel-Manganese Cobalt
- Lithium-Titanate Oxide
By End Use
- Automotive
- Industrial
- Consumer Electronics
By Recycling Process
- Hydro metallurgical Process
- Physical/Mechanical Process
- Pyrometallurgy Process
The regional analysis of the lithium-ion battery recycling market is as follows:
North America
- U.S.
- Canada
- Mexico
Europe
- UK
- Germany
- France
- Russia
- Italy
- Spain
- Rest of Europe
Asia-Pacific
- China
- India
- Japan
- Australia
- Rest of Asia-Pacific
Latin America
- Brazil
- Mexico
- Argentina
- Chile
Middle East & Africa
- South Africa
- UAE
- Saudi Arabia
- Israel
Key players operating in the lithium-ion battery recycling industry are:
- Fortum
- Glencore International AG
- International Metals Reclamation Company
- Neometals Ltd
- OnTo Technologies LLC
- Raw Materials Company Inc. (RMC)
- Redwood Materials Inc.
- Recupyl Sas
- Retriev Technologies Inc.
- Umicore
Lithium-Ion Battery Recycling Market: Who Should Purchase, and How It Will Help Readers
- The report is best suited for top-level decision-makers, individuals who are supposed to take a leadership role or require market research to start a business, independent researchers, research institutes, and anyone who wishes to gain detailed strategic insights into the lithium-ion battery recycling market.
- This report provides a qualitative and quantitative analysis of the market segments, current trends, estimations, and dynamics of the lithium-ion battery recycling market analysis from 2018 to 2033 to identify the prevailing market opportunities.
- Market research and information related to key drivers, restraints, and opportunities are offered.
- Porter's five forces and PESTLE analysis highlight the potency of buyers and suppliers to enable stakeholders' market profit-oriented business decisions and strengthen their supplier-buyer network.
- An in-depth analysis of the lithium-ion battery recycling segmentation assists in determining the prevailing market opportunities.
- Major countries in each region are mapped according to their revenue contribution to the global market.
- Market player positioning facilitates benchmarking and provides a clear understanding of the present position of the market players.
- The report includes an analysis of the regional and global lithium-ion battery recycling industry trends, key players, market segments, application areas, and market growth strategies.
- The report offers insights from primary interviews and CXOs of major industry players. It also offers a comprehensive contact and event repository to ensure future collaborations among industry stakeholders.
Lithium-Ion Battery Recycling Market: Frequently Asked Questions (FAQ)
Q: How big is the lithium-ion battery recycling market?
A: The global lithium-ion battery recycling market showcased a revenue of USD 3.9 billion in 2022 and is projected to witness a compounded annual growth rate (CAGR) of more than 21.14% over the forecast period of 2023-2033.
Q: Does the report have several lithium-ion battery recycling numbers bifurcated by segments and regions?
A: The report offers a total number of lithium-ion battery recycling market , further bifurcated into segments and regions. Please refer to the TOC page for more information.
Q: What are the major trends in the lithium-ion battery recycling market?
A: Proliferation in demand for electric vehicles, decrease in lithium-ion battery prices, and growing awareness of environmental degradation affect Lithium-ion battery recycling market growth.
Q: How can I get the sample Report on the lithium-ion battery recycling market?
A: The lithium-ion battery recycling market report sample can be obtained on demand from the website. Also, 24*7 chat support and direct call services are provided to procure the sample report
Q: Is it possible to purchase a specific or customized report as per my needs
A: Yes, it is possible to purchase a specific part of the report or edit the scope of the report at your convenience. Feel free to drop us the mail/talk to our customer support or schedule a conversation to procure a customized report.
Report Coverage
- Battery Chemistry
- End Use
- Recycling Process
- North America
- Europe
- Asia-Pacific
- Latin America
- Middle East & Africa
- Increasing demand for electric vehicles increasing consumption of lithium-ion batteries boosting market growth for recycling
- Decreasing prices of lithium-ion batteries to increase demand in the power industry,creating market demand for recycling
- Supply chain threat to hinder lithium-ion battery demand hindering the recycling market
Fortum, Glencore International AG, International Metals Reclamation Company, Neometals Ltd, OnTo Technologies LLC, Raw Materials Company Inc. (RMC), Redwood Materials Inc., Recupyl Sas, Retriev Technologies Inc., and Umicore.
1. Introduction
1.1 Report Description
1.1.1 Definition
1.1.2 Abbreviations
1.2 Key Market Segments
1.3 Benefits to Stakeholders
1.4 Research Methodology
1.4.1 Market Scoping
1.4.1.1 Problem Identification
1.4.1.2 Defining the Market
1.4.2 Market Estimation
1.4.2.1 Data Mining
1.4.2.2 Product Analysis
1.4.2.3 Application Analysis
1.4.2.4 Market Engineering and Forecasting
1.4.2.4.1 Bottom-up Demand Side
1.4.2.4.2 Bottom-up Supply side
1.4.3 Market Authentication
1.4.3.1 Data Triangulation
1.4.3.1.1 Top-down Supply Side
1.4.3.1.2 Top-down Demand Side
1.4.3.1.3 Data Triangulation
1.4.3.2 Primary Insights and Industry feedback
1.4.4 Report Writing
2. Executive Summary
2.1 Market Snapshot
2.2 Macro Trends, Global Economic Factors and Import/Export Insights
2.3 Primary Insights
2.4 Battery Chemistry Insights
2.5 End Use Insights
2.6 Recycling Process Insights
2.7 Regional Insights
3. Market Overview
3.1 Market Segment and Scope
3.2 Top Investment Pockets
3.3 Key Strategic Initiatives
3.4 Lithium-Ion Battery Recycling Market Industry Ecosystem
3.5 Market Evolution
3.6 Patent Analysis
3.7 Technology Landscape
3.8 Regulatory Infrastructure
3.9 Porter’s Analysis
3.9.1 Bargaining Power of Buyer
3.9.2 Bargaining Power of Supplier
3.9.3 Threat of New Entrants
3.9.4 Threat of Substitutes
3.9.5 Industry Rivalry
3.10 PESTLE Analysis
3.11 Market Dynamics
3.11.1 Drivers
3.11.2 Restrains
3.11.3 Opportunities
3.12 Impact of COVID-19 on Lithium-Ion Battery Recycling Market
3.13 Russia-Ukraine War Impact on Lithium-Ion Battery Recycling Market
3.14 Growth Share Matrix
3.15 Lithium-Ion Battery Recycling Market Quadrant
4. Lithium-Ion Battery Recycling Market, By Battery Chemistry
4.1 Major Impacting Factors, By Battery Chemistry
4.1.1 Key Market Trends and Growth Factors
4.1.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
4.1.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
4.2 Lithium-Ion Phosphate
4.2.1 Key Market Trends and Growth Factors
4.2.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
4.2.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
4.3 Lithium-Manganese Oxide
4.3.1 Key Market Trends and Growth Factors
4.3.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
4.3.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
4.4 Lithium-Nickel-Cobalt-Aluminum Oxide
4.4.1 Key Market Trends and Growth Factors
4.4.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
4.4.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
4.5 Lithium-Nickel-Manganese Cobalt
4.5.1 Key Market Trends and Growth Factors
4.5.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
4.5.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
4.6 Lithium-Titanate Oxide
4.6.1 Key Market Trends and Growth Factors
4.6.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
4.6.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
5. Lithium-Ion Battery Recycling Market, By End Use
5.1 Major Impacting Factors, By End Use
5.1.1 Key Market Trends and Growth Factors
5.1.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
5.1.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
5.2 Automotive
5.2.1 Key Market Trends and Growth Factors
5.2.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
5.2.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
5.3 Industrial
5.3.1 Key Market Trends and Growth Factors
5.3.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
5.3.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
5.4 Consumer Electronics
5.4.1 Key Market Trends and Growth Factors
5.4.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
5.4.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
6. Lithium-Ion Battery Recycling Market, By Recycling Process
6.1 Major Impacting Factors, By Recycling Process
6.1.1 Key Market Trends and Growth Factors
6.1.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
6.1.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
6.2 Hydro Metallurgical Process
6.2.1 Key Market Trends and Growth Factors
6.2.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
6.2.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
6.3 Physical/Mechanical Process
6.3.1 Key Market Trends and Growth Factors
6.3.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
6.3.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
6.4 Pyrometallurgy Process
6.4.1 Key Market Trends and Growth Factors
6.4.2 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
6.4.3 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
7. Lithium-Ion Battery Recycling Market, By Region
7.1 Global Market Trends and Growth Factors
7.2 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.3 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.4 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.5 Market Size and Forecast, by Region, 2017-2032, (USD Billion)
7.6 North America
7.6.1 Key Market Trends and Growth Factors
7.6.2 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.6.3 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.6.4 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.6.5 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
7.6.6 U.S.
7.6.6.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.6.6.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.6.6.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.6.7 Canada
7.6.7.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.6.7.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.6.7.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.6.8 Mexico
7.6.8.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.6.8.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.6.8.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.7 Europe
7.7.1 Key Market Trends and Growth Factors
7.7.2 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.7.3 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.7.4 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.7.5 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
7.7.6 UK
7.7.6.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.7.6.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.7.6.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.7.7 Germany
7.7.7.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.7.7.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.7.7.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.7.8 France
7.7.8.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.7.8.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.7.8.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.7.9 Russia
7.7.9.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.7.9.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.7.9.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.7.10 Italy
7.7.10.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.7.10.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.7.10.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.7.11 Rest of Europe
7.7.11.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.7.11.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.7.11.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.8 Asia-Pacific
7.8.1 Key Market Trends and Growth Factors
7.8.2 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.8.3 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.8.4 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.8.5 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
7.8.6 China
7.8.6.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.8.6.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.8.6.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.8.7 India
7.8.7.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.8.7.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.8.7.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.8.8 Japan
7.8.8.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.8.8.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.8.8.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.8.9 Australia
7.8.9.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.8.9.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.8.9.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.8.10 Rest of Asia-Pacific
7.8.10.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.8.10.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.8.10.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.9 Latin America
7.9.1 Key Market Trends and Growth Factors
7.9.2 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.9.3 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.9.4 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.9.5 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
7.9.6 Brazil
7.9.6.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.9.6.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.9.6.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.9.7 Argentina
7.9.7.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.9.7.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.9.7.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.9.8 Mexico
7.9.8.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.9.8.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.9.8.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.9.9 Chile
7.9.9.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.9.9.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.9.9.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.10 Middle East and Africa
7.10.1 Key Market Trends and Growth Factors
7.10.2 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.10.3 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.10.4 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.10.5 Market Size and Forecast, by Country, 2017-2032, (USD Billion)
7.10.6 South Africa
7.10.6.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.10.6.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.10.6.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.10.7 UAE
7.10.7.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.10.7.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.10.7.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.10.8 Saudi Arabia
7.10.8.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.10.8.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.10.8.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
7.10.9 Israel
7.10.9.1 Market Size and Forecast, by Battery Chemistry, 2017-2032, (USD Billion)
7.10.9.2 Market Size and Forecast, by End Use, 2017-2032, (USD Billion)
7.10.9.3 Market Size and Forecast, by Recycling Process, 2017-2032, (USD Billion)
8. Competitive Benchmarking & Company Profiles
8.1 Competitive Benchmarking
8.1.1 Company Market Share
8.1.2 Product Mapping
8.1.3 Competitive Heat map
8.2 Fortum
8.2.1 Company Overview
8.2.2 Financial Analysis
8.2.3 Product Offering
8.2.4 Strategic Initiatives
8.2.5 SWOT
8.2.6 Ansoff Matrix
8.3 Glencore International AG
8.3.1 Company Overview
8.3.2 Financial Analysis
8.3.3 Product Offering
8.3.4 Strategic Initiatives
8.3.5 SWOT
8.3.6 Ansoff Matrix
8.4 International Metals Reclamation Company
8.4.1 Company Overview
8.4.2 Financial Analysis
8.4.3 Product Offering
8.4.4 Strategic Initiatives
8.4.5 SWOT
8.4.6 Ansoff Matrix
8.5 Neometals Ltd
8.5.1 Company Overview
8.5.2 Financial Analysis
8.5.3 Product Offering
8.5.4 Strategic Initiatives
8.5.5 SWOT
8.5.6 Ansoff Matrix
8.6 OnTo Technologies LLC
8.6.1 Company Overview
8.6.2 Financial Analysis
8.6.3 Product Offering
8.6.4 Strategic Initiatives
8.6.5 SWOT
8.6.6 Ansoff Matrix
8.7 Raw Materials Company Inc. (RMC)
8.7.1 Company Overview
8.7.2 Financial Analysis
8.7.3 Product Offering
8.7.4 Strategic Initiatives
8.7.5 SWOT
8.7.6 Ansoff Matrix
8.8 Redwood Materials Inc.
8.8.1 Company Overview
8.8.2 Financial Analysis
8.8.3 Product Offering
8.8.4 Strategic Initiatives
8.8.5 SWOT
8.8.6 Ansoff Matrix
8.9 Recupyl Sas
8.9.1 Company Overview
8.9.2 Financial Analysis
8.9.3 Product Offering
8.9.4 Strategic Initiatives
8.9.5 SWOT
8.9.6 Ansoff Matrix
8.10 Retriev Technologies Inc.
8.10.1 Company Overview
8.10.2 Financial Analysis
8.10.3 Product Offering
8.10.4 Strategic Initiatives
8.10.5 SWOT
8.10.6 Ansoff Matrix
8.11 Umicore
8.11.1 Company Overview
8.11.2 Financial Analysis
8.11.3 Product Offering
8.11.4 Strategic Initiatives
8.11.5 SWOT
8.11.6 Ansoff Matrix
9. Industry Connects and Upcoming Seminars
