封面
市場調查報告書
商品編碼
1270972

全球電動汽車陰極材料市場:按供應、按需求、按電池類型(鋰離子、鉛酸、其他)、按地區 - 考慮到 COVID-19 影響的規模和趨勢,預測至 2028 年

Global EV Cathode Material Market: Analysis By Supply, By Demand, By Battery Type (Lithium ion Battery, Lead Acid Battery & Other), By Region Size and Trends with Impact of COVID-19 and Forecast up to 2028

出版日期: | 出版商: Daedal Research | 英文 163 Pages | 訂單完成後即時交付

價格

全球 EV 陰極材料市場規模預計將從 2022 年的 65.8 億美元增長到 2028 年的 107.7 億美元,在 2023 年至 2028 年的預測期內。複合年增長率為 8%。 世界各國政府越來越多地推廣電動汽車,增加政府補貼和清潔能源正在推動市場的增長。

本報告探討了全球電動汽車正極材料市場,並提供了全面的信息,包括市場分析、競爭格局和公司概況。

內容

第 1 章執行摘要

第二章介紹

  • 陰極材料:概述
    • EV 陰極材料的定義
    • 正極材料類型
  • 陰極材料的細分:概述
    • 正極材料細分

第三章全球市場分析

  • 全球電動汽車正極材料市場:分析
    • 全球電動汽車正極材料市場:概覽
    • 全球 EV 陰極材料市場:按價值
    • 按電池類型劃分的全球 EV 陰極材料市場
    • 全球電動汽車正極材料市場:按地區
  • 全球電動汽車正極材料市場:供應分析
    • 全球電動汽車陰極材料市場:概覽:按供應分類
    • 全球電動汽車陰極材料市場:按供應分類
    • 全球電動汽車正極材料市場供應:按類型分類
    • 全球電動汽車正極材料市場供應:按地區分類
  • 全球電動汽車正極材料市場:需求分析
    • 全球電動汽車陰極材料市場:概覽:按需求
    • 全球電動汽車正極材料市場:按需求分類
    • 全球電動汽車正極材料市場需求:按類型分類
  • 全球電動汽車正極材料市場:電池類型分析
    • 全球電動汽車陰極材料市場:概覽:按電池類型分類
    • 全球鋰離子電池 EV 陰極材料市場:按價值
    • 全球鉛酸電池 EV 陰極材料市場:按價值
    • 世界其他電動汽車正極材料市場:按價值
  • 全球電動汽車正極材料市場供應:類型分析
    • 全球電動汽車陰極材料市場供應:概覽:按類型分類
    • 全球 NMC/NCA EV 陰極材料市場:按供應分類
    • 全球 LFP EV 陰極材料市場:按供應分類
  • 全球電動汽車正極材料市場需求:類型分析
    • 全球電動汽車陰極材料市場需求:概覽:按類型分類
    • 全球 NMC/NCA EV 陰極材料市場:按需求分類
    • 全球 LFP EV 陰極材料市場:按需求分類

第四章區域市場分析

  • 亞太地區電動汽車正極材料市場:分析
  • 北美 EV 陰極材料市場:分析
  • 歐洲 EV 正極材料市場:分析
  • 其他 EV 正極材料市場:分析

第 5 章 COVID-19 的影響

  • COVID-19 的影響
    • 新型冠狀病毒肺炎 (COVID-19) 對全球電動汽車正極材料市場的影響
    • COVID-19 對全球電動汽車銷售的影響
    • COVID-19 之後的情景

第 6 章市場動態

  • 推動增長的因素
    • 擴大電動汽車的引進
    • 飆升的燃油價格
    • 環境問題日益嚴重
    • 鋰離子電池價格下降
    • 增加政府補貼和清潔能源
  • 任務
    • 原材料的不穩定和安全問題
    • 增加與 NCM 相關的環境影響
    • 鋰離子電池正極材料開發中的問題
  • 市場趨勢
    • 加強對內燃機車輛的禁令
    • 對零排放汽車的需求激增
    • 擴大向可再生能源消費的轉變
    • 電池技術的最新發展

第七章競爭格局

  • 電動汽車陰極材料的全球供應:主要比較:按公司分類

第八章公司簡介

  • BASF SE
  • 3M Company
  • Umicore SA
  • POSCO Future M Co., Ltd.
  • Mitsubishi Chemical Group Corporation
  • Johnson Matthey PLC
  • Kureha Corporation
  • Mitsui Mining & Smelting Co., Ltd.
  • Sumitomo Metal Mining Co., Ltd.
  • LG Corporation (LG Chem Ltd.)
  • Hitachi Ltd. (Hitachi Metals, Ltd.)
  • Toda Kogyo Corp.
  • NEI Corporation

The global EV cathode material market in 2022 was valued at US$6.58 billion. The market is expected to reach US$10.77 billion by 2028. Cathode material are the main component of Li-ion & lead acid batteries, as they determine the energy density of a cell through cell voltage. Cathode materials comprise cobalt, nickel, and manganese in the crystal structure forming a multi-metal oxide material to which lithium is added. These define the output and application of different types of rechargeable lithium-ion batteries used in electric vehicles.

The growing adoption of electric vehicles which is being supported by the rising government subsidies & clean energy as government of different countries are promoting electric vehicles with the subsidies, policy changes and regulation on carbon emissions, is also a major reason behind the growing demand for cathode materials in the sector. Therefore, the rising government subsidies & clean energy is one of the main factors that would drive the demand for EV cathode material in the forthcoming years. The market is expected to grow at a CAGR of approx. 8% during the forecasted period of 2022-2028.

Market Segmentation Analysis:

By Battery Type: The report provides the bifurcation of the market into three segments based on the types of battery: Lithium-Ion Battery, Lead Acid Battery and other battery types. In 2022, Lithium-ion battery held a major share in the market. On the other hand, Lead acid battery segment is expected to grow at the highest CAGR in the forthcoming years as lead dioxide and lead have the lowest energy densities and rarely discharge highly efficiently, leading to its growing adoption. Along with this, Lead-acid cathode materials are up to ten times cheaper than modern nickel-metal hydride, lithium-ion, and lithium-polymer batteries being developed for high-performance automobiles, further expected to propel the overall market growth lead acid battery type in the coming years.

By Region: The report provides insight into the EV cathode material market based on the regions Asia Pacific, North America, Europe, and ROW. Asia Pacific held the major share in the market owing to the increasing investment by major electric vehicle manufacturers and availability of cheap labour in the region. China market dominated the region due to the swiftly escalating year-on-year adoption rate of mild-hybrid electric vehicles across the region.

In North America, the US is the dominating region. Whereas, in Europe, the UK dominated the market owing to the rising supportive government policies and regulations, increasing environmental concerns, and growing adoption of electric mobility in the region.

By Supply: In the report, the global EV cathode material market supply is given as cathode materials are gaining momentum as a significant components of rechargeable batteries, such as nickel-metal hydride batteries, lithium-ion batteries, and others. One of the primary reasons for the rising trend in EV cathode material supply is the increasing number of strengthened rules for phasing for internal combustion engines and rising incentives and subsidies for EV adoption. The global EV cathode material market by supply is divided into six regions namely, China, South Korea, Japan, Europe, the US, and rest of the World. In 2022, the global EV cathode material supply was dominated by China, accounting for more than half of the global EV cathode material supply which is anticipated to grow manifolds in the forecasted period, due to the increasing adoption of EVs in the economy.

By Type: In the report, the global EV cathode material supply is further divided based on type: NMC (Lithium Nickel Cobalt Manganese Oxide)/NCA (Lithium Nickel Cobalt Aluminium Oxide), and LFP (Lithium Ferrous Phosphate). NMC/NCA dominated the supply of the EV cathode material market in the year 2022. NMC/NCA is the largest category of EV cathode materials. Ternary cathode materials (NMC) have nickel, manganese and cobalt as their principal components, and as the cathode materials for lithium ion secondary batteries, are used mainly in batteries aimed at electrically-powered cars, including hybrid vehicles. Growing demand for lithium nickel cobalt aluminum oxide (NCA) due to its high specific power, specific energy and long lifespan is anticipated to increase the growth of the NMC/NCA supply during forecast period.

By Demand: The report provides a glimpse of the EV cathode material demand around the world. One of the primary reasons for the rising trend in EV cathode material demand is the increasing adoption of electric vehicles, which require large quantities of lithium-ion batteries. Electric vehicles require large quantities of lithium-ion batteries, which in turn require significant amounts of cathode materials. The cathode materials demand is also benefiting from increased investment in research and development projects, which is expected to result in higher demand for these materials in coming years.

By Type: In the report, the global EV cathode material demand is further divided based on on type: NMC (Lithium Nickel Cobalt Manganese Oxide)/NCA (Lithium Nickel Cobalt Aluminium Oxide), and LFP (Lithium Ferrous Phosphate). NMC/NCA dominated the supply of the EV cathode material market in the year 2022. With increasing environmental degradation and the deteriorating air quality levels in several countries, the deployment of electric vehicles is increasing rapidly. This is, in turn, pushing up the requirement for lithium-ion batteries, which is subsequently causing the expansion of the cathode material for electric vehicle lithium-ion batteries.

Market Dynamics:

Growth Drivers: The global EV cathode material market has been growing over the past few years, due to factors such as growing adoption of electric vehicles, escalating fuel prices, mounting environmental concerns, declining prices of lithium-ion-battery, and many other factors. Additionally, the rising government subsidies & clean energy is one of the most significant drivers for EV cathode material, as government of different countries are promoting electric vehicles with the subsidies, policy changes and regulation on carbon emissions, leading to growing demand for cathode materials in the sector. Moreover, the declining prices of Lithium-ion batteries, to support to the increasing demand for cathode materials as these are the main component of Li-ion batteries and they determine the energy density of a cell through cell voltage and/or capacity.

Challenges: However, the market has been confronted with some challenges specifically, instability of raw material and safety issues, increasing environmental impacts associated with NCM and developmental issues in cathode materials for Li-ion batteries, etc.

Trends: The market is projected to grow at a fast pace during the forecast period, due to various latest trends such as increasing ban on ICE vehicles, surging demand for zero emission vehicles, growing shift towards renewable consumption, etc. Additionally, the ongoing developments in battery technology is one of the most significant drivers for EV cathode material, as improved battery technology is critical for advancements in a variety of applications ranging from hybrid electric vehicles to consumer electronics, and improved battery performance depends on the development of materials for the various battery components, which is expected to offer lucrative opportunities for the EV cathode material market in the future.

Impact Analysis of COVID-19 and Way Forward:

The COVID-19 pandemic had an adverse effect on the overall automotive industry and electric vehicle & EV battery industries. The sales of electric vehicles were hampered due to the pandemic for a short term. Many countries imposed travel restrictions on material flow in and out of China, which significantly reduced the customer base for a large number of industrial electric-powered tools. However, the industry has bounced back with higher growth than that of the previous years' owing to the consistent rise in fuel prices and rising concerns towards environmental pollution coupled with provision of the subsidies by various governments.

Competitive Landscape:

The global EV cathode material market is fragmented, with key players operating on global and regional levels. The key players in the global EV cathode material market are:

BASF SE

3M Company

Umicore SA

POSCO Future M Co., Ltd.

Mitsubishi Chemical Group Corporation

Johnson Matthey PLC

Kureha Corporation

Mitsui Mining & Smelting Co., Ltd.

Sumitomo Metal Mining Co., Ltd.

LG Corporation (LG Chem Ltd.)

Hitachi Ltd. (Hitachi Metals, Ltd.)

Toda Kogyo Corp.

NEI Corporation

Some of the strategies among key players in the market for EV cathode materials are platform development and strategic alliances to expand their respective portfolios and gain a robust footing in the global market. For instance, in May 2022, Umicore inaugurated their new global R&D center for Cathode Materials in Cheonan, Korea. It will focus on producing the next generation of battery materials, including very high-nickel NMC, low-cobalt NMC, manganese-rich chemistries, and solid-state battery technologies. Whereas, in April 2022, POSCO Chemicals announced that they began constructing their new manufacturing plant capable of producing 30,000 tons of high-purity nickel cathodes. This is expected to help the company to expand its consumer base for the cathode materials market. 

Table of Contents

    1. Executive Summary

    2. Introduction

    • 2.1 Cathode Materials: An Overview
      • 2.1.1 Definition of Cathode Materials for Electric Vehicles
      • 2.1.2 Types of Cathode Active Materials
    • 2.2 Cathode Materials Segmentation: An Overview
      • 2.2.1 Cathode Materials Segmentation

    3. Global Market Analysis

    • 3.1 Global EV Cathode Material Market: An Analysis
      • 3.1.1 Global EV Cathode Material Market: An Overview
      • 3.1.2 Global EV Cathode Material Market by Value
      • 3.1.3 Global EV Cathode Material Market by Battery Type
      • 3.1.4 Global EV Cathode Material Market by Region
    • 3.2 Global EV Cathode Material Market: Supply Analysis
      • 3.2.1 Global EV Cathode Material Market by Supply: An Overview
      • 3.2.2 Global EV Cathode Material Market by Supply
      • 3.2.3 Global EV Cathode Material Market Supply by Type
      • 3.2.4 Global EV Cathode Material Market Supply by Region
    • 3.3 Global EV Cathode Material Market: Demand Analysis
      • 3.3.1 Global EV Cathode Material Market by Demand: An Overview
      • 3.3.2 Global EV Cathode Material Market by Demand
      • 3.3.3 Global EV Cathode Material Market Demand by Type
    • 3.4 Global EV Cathode Material Market: Battery Type Analysis
      • 3.4.1 Global EV Cathode Material Market By Battery Type: An Overview
      • 3.4.2 Global Lithium-Ion EV Cathode Material Market by Value
      • 3.4.3 Global Lead Acid EV Cathode Material Market by Value
      • 3.4.4 Global Other Batteries EV Cathode Material Market by Value
    • 3.5 Global EV Cathode Material Market Supply: Type Analysis
      • 3.5.1 Global EV Cathode Material Market Supply by Type: An Overview
      • 3.5.2 Global NMC/NCA EV Cathode Material Market by Supply
      • 3.5.3 Global LFP EV Cathode Material Market by Supply
    • 3.6 Global EV Cathode Material Market Demand: Type Analysis
      • 3.6.1 Global EV Cathode Material Market Demand by Type: An Overview
      • 3.6.2 Global NMC/NCA EV Cathode Material Market by Demand
      • 3.6.3 Global LFP EV Cathode Material Market by Demand

    4. Regional Market Analysis

    • 4.1 Asia Pacific EV Cathode Material Market: An Analysis
      • 4.1.1 Asia Pacific EV Cathode Material Market: An Overview
      • 4.1.2 Asia Pacific EV Cathode Material Market by Value
      • 4.1.3 Asia Pacific EV Cathode Material Market by Region
      • 4.1.4 China EV Cathode Material Market by Value
      • 4.1.5 China EV Cathode Material Market by Supply
      • 4.1.6 Japan EV Cathode Material Market by Value
      • 4.1.7 Japan EV Cathode Material Market by Supply
      • 4.1.8 South Korea EV Cathode Material Market by Value
      • 4.1.9 South Korea EV Cathode Material Market by Supply
      • 4.1.10 India EV Cathode Material Market by Value
      • 4.1.11 Rest of Asia Pacific EV Cathode Material Market by Value
    • 4.2 North America EV Cathode Material Market: An Analysis
      • 4.2.1 North America EV Cathode Material Market: An Overview
      • 4.2.2 North America EV Cathode Material Market by Value
      • 4.2.3 North America EV Cathode Material Market by Region
      • 4.2.4 The US EV Cathode Material Market by Value
      • 4.2.5 The US EV Cathode Material Market by Supply
      • 4.2.6 Canada EV Cathode Material Market by Value
      • 4.2.7 Mexico EV Cathode Material Market by Value
    • 4.3 Europe EV Cathode Material Market: An Analysis
      • 4.3.1 Europe EV Cathode Material Market: An Overview
      • 4.3.2 Europe EV Cathode Material Market by Value
      • 4.3.3 Europe EV Cathode Material Market by Region
      • 4.3.4 Europe EV Cathode Material Market by Supply
      • 4.3.5 United Kingdom EV Cathode Material Market by Value
      • 4.3.6 Germany EV Cathode Material Market by Value
      • 4.3.7 France EV Cathode Material Market by Value
      • 4.3.8 Italy EV Cathode Material Market by Value
      • 4.3.9 Rest of Europe EV Cathode Material Market by Value
    • 4.4 Rest of the World EV Cathode Material Market: An Analysis
      • 4.4.1 Rest of the World EV Cathode Material Market: An Overview
      • 4.4.2 Rest of the World EV Cathode Material Market by Value
      • 4.4.3 Rest of the World EV Cathode Material Market by Supply

    5. Impact of COVID-19

    • 5.1 Impact of COVID-19
      • 5.1.1 Impact of COVID-19 on Global EV Cathode Material Market
      • 5.1.2 Impact of COVID-19 on Global Electric Vehicle Sales
      • 5.1.3 Post-COVID Scenario

    6. Market Dynamics

    • 6.1 Growth Drivers
      • 6.1.1 Growing Adoption of Electric Vehicles
      • 6.1.2 Escalating Fuel Prices
      • 6.1.3 Mounting Environmental Concerns
      • 6.1.4 Declining Prices of Lithium-ion-Battery
      • 6.1.5 Rising Government Subsidies & Clean Energy
    • 6.2 Challenges
      • 6.2.1 Instability of Raw Material and Safety Issues
      • 6.2.2 Increasing Environmental Impacts Associated with NCM
      • 6.2.3 Developmental Issues in Cathode Materials for Li-ion Batteries
    • 6.3 Market Trends
      • 6.3.1 Increasing Ban on ICE Vehicles
      • 6.3.2 Surging Demand for Zero Emission Vehicles
      • 6.3.3 Growing Shift Towards Renewable Consumption
      • 6.3.4 Recent Developments in Battery Technology

    7. Competitive Landscape

    • 7.1 Global EV Cathode Material Supply by Players: Key Comparison

    8. Company Profiles

    • 8.1 BASF SE
      • 8.1.1 Business Overview
      • 8.1.2 Operating Segment
      • 8.1.3 Business Strategy
    • 8.2 3M Company
      • 8.2.1 Business Overview
      • 8.2.2 Operating Segments
      • 8.2.3 Business Strategy
    • 8.3 Umicore SA
      • 8.3.1 Business Overview
      • 8.3.2 Operating Segments
      • 8.3.3 Business Strategy
    • 8.4 POSCO Future M Co., Ltd.
      • 8.4.1 Business Overview
      • 8.4.2 Operating Segments
      • 8.4.3 Business Strategy
    • 8.5 Mitsubishi Chemical Group Corporation
      • 8.5.1 Business Overview
      • 8.5.2 Operating Segment
      • 8.5.3 Business Strategy
    • 8.6 Johnson Matthey PLC
      • 8.6.1 Business Overview
      • 8.6.2 Operating Segment
      • 8.6.3 Business Strategy
    • 8.7 Kureha Corporation
      • 8.7.1 Business Overview
      • 8.7.2 Operating Segment
      • 8.7.3 Business Strategy
    • 8.8 Mitsui Mining & Smelting Co., Ltd.
      • 8.8.1 Business Overview
      • 8.8.2 Operating Segment
      • 8.8.3 Business Strategy
    • 8.9 Sumitomo Metal Mining Co., Ltd.
      • 8.9.1 Business Overview
      • 8.9.2 Business Segments
      • 8.9.3 Business Strategy
    • 8.10 LG Corporation (LG Chem Ltd.)
      • 8.10.1 Business Overview
      • 8.10.2 Operating Segment
      • 8.10.3 Business Strategy
    • 8.11 Hitachi Ltd. (Hitachi Metals, Ltd.)
      • 8.11.1 Business Overview
      • 8.11.2 Operating Segments
      • 8.11.3 Business Strategy
    • 8.12 Toda Kogyo Corp.
      • 8.12.1 Business Overview
      • 8.12.2 Operating Region
      • 8.12.3 Business Strategy
    • 8.13 NEI Corporation
      • 8.13.1 Business Overview
      • 8.13.2 Business Strategy

List of Tables

  • Table 1: Types of Cathode Active Materials
  • Table 2: Upcoming ICE Vehicles Ban by Countries
  • Table 3: Global EV Cathode Material Supply by Players: Key Comparison

List of Figures

  • Figure 1: Cathode Materials Segmentation
  • Figure 2: Global EV Cathode Material Market by Value; 2018-2022 (US$ Billion)
  • Figure 3: Global EV Cathode Material Market by Value; 2023-2028 (US$ Billion)
  • Figure 4: Global EV Cathode Material Market by Battery Type; 2022 (Percentage, %)
  • Figure 5: Global EV Cathode Material Market by Region; 2022 (Percentage, %)
  • Figure 6: Global EV Cathode Material Market by Supply; 2018-2022 (Million Tons)v Figure 7: Global EV Cathode Material Market by Supply; 2023-2028 (Million Tons)
  • Figure 8: Global EV Cathode Material Supply Market by Type; 2022 (Percentage, %)
  • Figure 9: Global EV Cathode Material Market Supply by Region; 2022 (Percentage, %)
  • Figure 10: Global EV Cathode Material Market by Demand; 2018-2022 (Million Tons)
  • Figure 11: Global EV Cathode Material Market by Demand; 2023-2028 (Million Tons)
  • Figure 12: Global EV Cathode Material Market Demand by Type; 2022 (Percentage, %)
  • Figure 13: Global Lithium-Ion EV Cathode Material Market by Value; 2018-2022 (US$ Billion)
  • Figure 14: Global Lithium-Ion EV Cathode Material Market by Value; 2023-2028 (US$ Billion)
  • Figure 15: Global Lead Acid EV Cathode Material Market by Value; 2018-2022 (US$ Billion)
  • Figure 16: Global Lead Acid EV Cathode Material Market by Value; 2023-2028 (US$ Billion)
  • Figure 17: Global Other Batteries EV Cathode Material Market by Value; 2018-2022 (US$ Million)
  • Figure 18: Global Other Batteries EV Cathode Material Market by Value; 2023-2028 (US$ Billion)
  • Figure 19: Global NMC/NCA EV Cathode Material Market by Supply; 2018-2022 (Million Tons)
  • Figure 20: Global NMC/NCA EV Cathode Material Market by Supply; 2023-2028 (Million Tons)
  • Figure 21: Global LFP EV Cathode Material Market by Supply; 2018-2022 (Thousand Tons)
  • Figure 22: Global LFP EV Cathode Material Market by Supply; 2023-2028 (Million Tons)
  • Figure 23: Global NMC/NCA EV Cathode Material Market by Demand; 2018-2022 (Thousand Tons)
  • Figure 24: Global NMC/NCA EV Cathode Material Market by Demand; 2023-2028 (Million Tons)
  • Figure 25: Global LFP EV Cathode Material Market by Demand; 2018-2022 (Thousand Tons)
  • Figure 26: Global LFP EV Cathode Material Market by Demand; 2023-2028 (Thousand Tons)
  • Figure 27: Asia Pacific EV Cathode Material Market by Value; 2018-2022 (US$ Billion)
  • Figure 28: Asia Pacific EV Cathode Material Market by Value; 2023-2028 (US$ Billion)
  • Figure 29: Asia Pacific EV Cathode Material Market by Region; 2022 (Percentage, %)
  • Figure 30: China EV Cathode Material Market by Value; 2018-2022 (US$ Billion)
  • Figure 31: China EV Cathode Material Market by Value; 2023-2028 (US$ Billion)
  • Figure 32: China EV Cathode Material Market by Supply; 2022-2028 (Million Tons)
  • Figure 33: Japan EV Cathode Material Market by Value; 2018-2022 (US$ Million)
  • Figure 34: Japan EV Cathode Material Market by Value; 2023-2028 (US$ Million)
  • Figure 35: Japan EV Cathode Material Market by Supply; 2022-2028 (Thousand Tons)
  • Figure 36: South Korea EV Cathode Material Market by Value; 2018-2022 (US$ Million)
  • Figure 37: South Korea EV Cathode Material Market by Value; 2023-2028 (US$ Million)
  • Figure 38: South Korea EV Cathode Material Market by Supply; 2022-2028 (Thousand Tons)
  • Figure 39: India EV Cathode Material Market by Value; 2018-2022 (US$ Million)
  • Figure 40: India EV Cathode Material Market by Value; 2023-2028 (US$ Million)
  • Figure 41: Rest of Asia Pacific EV Cathode Material Market by Value; 2018-2022 (US$ Million)
  • Figure 42: Rest of Asia Pacific EV Cathode Material Market by Value; 2023-2028 (US$ Million)
  • Figure 43: North America EV Cathode Material Market by Value; 2018-2022 (US$ Billion)
  • Figure 44: North America EV Cathode Material Market by Value; 2023-2028 (US$ Billion)
  • Figure 45: North America EV Cathode Material Market by Region; 2022 (Percentage,%)
  • Figure 46: The US EV Cathode Material Market by Value; 2018-2022 (US$ Billion)
  • Figure 47: The US EV Cathode Material Market by Value; 2023-2028 (US$ Billion)
  • Figure 48: The US EV Cathode Material Market by Supply; 2022-2028 (Thousand Tons)
  • Figure 49: Canada EV Cathode Material Market by Value; 2018-2022 (US$ Million)
  • Figure 50: Canada EV Cathode Material Market by Value; 2023-2028 (US$ Million)
  • Figure 51: Mexico EV Cathode Material Market by Value; 2018-2022 (US$ Million)
  • Figure 52: Mexico EV Cathode Material Market by Value; 2023-2028 (US$ Million)
  • Figure 53: Europe EV Cathode Material Market by Value; 2018-2022 (US$ Billion)
  • Figure 54: Europe EV Cathode Material Market by Value; 2023-2028 (US$ Billion)
  • Figure 55: Europe EV Cathode Material Market by Region; 2022 Percentage,%)
  • Figure 56: Europe EV Cathode Material Market by Supply; 2022-2028 (Thousand Tons)
  • Figure 57: United Kingdom EV Cathode Material Market by Value; 2018-2022 (US$ Million)
  • Figure 58: United Kingdom EV Cathode Material Market by Value; 2023-2028 (US$ Million)
  • Figure 59: Germany EV Cathode Material Market by Value; 2018-2022 (US$ Million)
  • Figure 60: Germany EV Cathode Material Market by Value; 2023-2028 (US$ Million)
  • Figure 61: France EV Cathode Material Market by Value; 2018-2022 (US$ Million)
  • Figure 62: France EV Cathode Material Market by Value; 2023-2028 (US$ Million)
  • Figure 63: Italy EV Cathode Material Market by Value; 2018-2022 (US$ Million)
  • Figure 64: Italy EV Cathode Material Market by Value; 2023-2028 (US$ Million)
  • Figure 65: Rest of Europe EV Cathode Material Market by Value; 2018-2022 (US$ Million)
  • Figure 66: Rest of Europe EV Cathode Material Market by Value; 2023-2028 (US$ Million)
  • Figure 67: Rest of the World EV Cathode Material Market by Value; 2018-2022 (US$ Million)
  • Figure 68: Rest of the World EV Cathode Material Market by Value; 2023-2028 (US$ Million)
  • Figure 69: Rest of the World EV Cathode Material Market by Supply; 2022-2028 (Thousand Tons)
  • Figure 70: Global Number of Battery Electric Vehicles in Use; 2019-2021 (Million)
  • Figure 71: Global Share of Electric Vehicles; 2017-2021 (Percentage, %)
  • Figure 72: The US Retail Fuel Prices; 2021-2022 (US$ Per Gallon)
  • Figure 73: Annual Carbon Dioxide Emissions Worldwide; 2018-2022 (Billion Metric Tons)
  • Figure 74: Global Lithium-ion Battery Pack Costs; 2019-2030 (US$ Per Kilowatt Hour)
  • Figure 75: Implied Global BEV Penetration; 2021-2026 (Percentage, %)
  • Figure 76: Global Renewable Consumption Forecast; 2018-2050 (Exajoules)
  • Figure 77: BASF SE Sales by Segment; 2022 (Percentage, %)
  • Figure 78: 3M Company Net Sales by Segment; 2022 (Percentage, %)
  • Figure 79: Umicore SA Total Turnover by Segment; 2022 (Percentage, %)
  • Figure 80: POSCO Future M Co., Ltd. Revenue by Business Division; 2022 (Percentage, %)
  • Figure 81: Mitsubishi Chemical Group Corporation Sales Revenue by Business Divisions; 2021 (Percentage, %)
  • Figure 82: Johnson Matthey PLC Revenue by Segment; 2021 (Percentage, %)
  • Figure 83: Kureha Corporation Net Sales by Segment; 2021 (Percentage, %)
  • Figure 84: Mitsui Mining & Smelting Co., Ltd. Sales by Segment; 2021 (Percentage, %)
  • Figure 85: Sumitomo Metal Mining Co., Ltd. Net Sales by Segment; 2021 (Percentage, %)
  • Figure 86: LG Chem Ltd. Revenue by Segment; 2022 (Percentage, %)
  • Figure 87: Hitachi Chemical Co., Ltd. Revenues by Segment; 2021 (Percentage, %)
  • Figure 88: Toda Kogyo Net Revenue by Region; 2021 (Percentage, %)