▶ 調査レポート

希土類元素の世界市場:動向・シェア・規模・予測

• 英文タイトル:Rare Earth Elements Market: Global Industry Trends, Share, Size, Growth, Opportunity and Forecast 2022-2027

IMARCが調査・発行した産業分析レポートです。希土類元素の世界市場:動向・シェア・規模・予測 / Rare Earth Elements Market: Global Industry Trends, Share, Size, Growth, Opportunity and Forecast 2022-2027 / MRC-IM30074資料のイメージです。• レポートコード:MRC-IM30074
• 出版社/出版日:IMARC / 2022年10月
• レポート形態:英文、PDF、125ページ
• 納品方法:Eメール
• 産業分類:化学
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レポート概要
グローバル調査会社のIMARC社は、2021年に83億ドルであった世界の希土類元素市場規模が、2022年から2027年の間にCAGR 15.2%で成長し、2027年までに184億ドルに達すると予測しています。本調査レポートでは、希土類元素の世界市場について総合的に調査・分析し、序論、範囲・調査手法、エグゼクティブサマリー、希土類元素の概要、鉱業経済学、世界の希土類元素市場における中国の役割、市場分析、希土類元素別の需要・供給分析、用途別(磁石、ニッケル水素電池、自動車触媒、ディーゼルエンジン、その他、イオン吸着粘土採掘&加工の概要、潜在的供給不足への対策、競争状況などの項目をまとめています。なお、本書に掲載されている企業情報には、Lynas Corporation Ltd., Arafura Resources Limited, Great Western Minerals Group Ltd., Avalon Advanced Materials Inc., Greenland Minerals Ltd, Alkane Resources Ltd, Neo Performance Materials, Iluka Resource Limited, IREL (India) Limited, Canada Rare Earths Corporationなどが含まれています。
・序論
・範囲・調査手法
・エグゼクティブサマリー
・希土類元素の概要
・鉱業経済学
・世界の希土類元素市場における中国の役割
・世界の希土類元素市場分析
・希土類元素別の需要・供給分析
・世界の希土類元素市場規模:用途別
- 磁石における市場規模
- ニッケル水素電池における市場規模
- 自動車触媒における市場規模
- ディーゼルエンジンにおける市場規模
- その他用途における市場規模
・イオン吸着粘土採掘&加工の概要
・潜在的供給不足への対策
・競争状況

The global rare earth elements market size reached US$ 8.3 Billion in 2021. Looking forward, IMARC Group expects the market to reach US$ 18.4 Billion by 2027, exhibiting a growth rate (CAGR) of 15.2% during 2022-2027. Keeping in mind the uncertainties of COVID-19, we are continuously tracking and evaluating the direct as well as the indirect influence of the pandemic. These insights are included in the report as a major market contributor.

Rare earth element (REE) is a group of seventeen elements that are found in the earth’s crust and exhibit similar chemical and physical properties. Cerium, neodymium, erbium, holmium, lanthanum, praseodymium, yttrium, and dysprosium are some of the widely used rare earth elements. These elements offer numerous benefits, such as high electrical conductivity, enhanced heat resistance, improved magnetism, weight reduction, etc. As a result, REEs find diverse applications across various end-use sectors, including automobile, transportation, power generation, construction, medical, defense, etc.

The expanding automobile industry is currently propelling the utilization of rare earth elements for manufacturing catalysts and magnets for motor vehicles. Furthermore, the rising environmental concerns towards the increasing CO2 emissions from fuel-driven automobiles are augmenting the demand for electric vehicles across the globe. These electric vehicles utilize numerous REE-based permanent magnets, such as neodymium and praseodymium magnets, in the production of high-efficiency batteries. Additionally, the implementation of stringent regulations pertaining to the mandatory installation of catalytic converters in automobiles to reduce emissions is also driving the market for rare earth elements. Apart from this, the increasing penetration of advanced energy generation facilities is further catalyzing the use of REEs in manufacturing turbines, reactors, generators, transformers, etc. Moreover, the growing popularity of smart electronic devices, including LED/LCD TVs, smartphones, laptops, smart wearables, etc., is also bolstering the demand for REE-based components. Additionally, the emergence of fiber optics is further propelling the utilization of various rare earth elements, such as neodymium, erbium, and holmium, for manufacturing high-efficiency fibers.

Key Market Segmentation:
IMARC Group provides an analysis of the key trends in each sub-segment of the global rare earth elements market report, along with forecasts at the global and regional level from 2022-2027. Our report has categorized the market based on application.

Breakup by Application:

Magnets
NiMH Batteries
Auto Catalysts
Diesel Engines
Fluid Cracking Catalyst
Phosphers
Glass
Polishing Powders
Others

Breakup by Region:

China
Japan & Northeast Asia
United States

Competitive Landscape:
The competitive landscape of the industry has also been examined along with the profiles of the key players being Lynas Corporation Ltd., Arafura Resources Limited, Great Western Minerals Group Ltd., Avalon Advanced Materials Inc., Greenland Minerals Ltd, Alkane Resources Ltd, Neo Performance Materials, Iluka Resource Limited, IREL (India) Limited and Canada Rare Earths Corporation.

Key Questions Answered in This Report
1. What are the key factors driving the global rare earth elements market?
2. What has been the impact of COVID-19 on the global rare earth elements market?
3. What is the breakup of the global rare earth elements market based on the application?
4. What are the key regions in the global rare earth elements market?

レポート目次

1 Preface
2 Scope and Methodology
2.1 Objectives of the Study
2.2 Stakeholders
2.3 Data Sources
2.3.1 Primary Sources
2.3.2 Secondary Sources
2.4 Market Estimation
2.4.1 Bottom-Up Approach
2.4.2 Top-Down Approach
2.5 Forecasting Methodology
3 Executive Summary
4 What are Rare Earth Elements?
5 Rare Earth Elements: Are they Really Rare?
5.1 Reserve Estimates
5.2 How Long Will They Last?
6 Rare Earth Elements: Mining Economics
6.1 Mine Valuation: Grades & Composition are Key
6.2 Development of a New Project: Can Take Several Years
6.3 Rare Earth Mining Costs: Largely Location and Grade Development
6.4 Infrastructure & Capital Costs
6.5 Operating Costs
6.6 Key Projects
6.6.1 Arafura Resources Limited-Noland Project
6.6.2 Nechalacho Rare Earth Elements Project
6.6.3 Kvanefjeld Project-Greenland Minerals & Energy Limited
6.6.4 Dubbo Zirconia-Alkane Resources Limited
6.7 Mining and Processing
6.7.1 Mining
6.7.2 Downstream Processing
6.8 Prices
6.8.1 Factors Affecting Rare Earth Element Prices
6.8.2 Historical Prices
6.8.3 Pricing Forecast
7 China’s Role in the Global Rare Earth Elements Market
7.1 China has a Monopoly Over Rare Earth Elements
7.2 Mining Costs in China Are Significantly Lower Than Other Rare Earth Producers
7.3 Miners Have Benefitted from the Lack of Proper Working Standards and Environmental Regulations
7.4 China Has a Significantly Higher In-house Expertise Compared to Other Rare Earth Producers
7.5 China is Strategically Increasing Production Quotas to Sustain Global Dominance in Rare Earth Elements Market
7.6 China Aims to Become an Exporter of Higher Value Goods
8 Global Rare Earth Elements Market
8.1 Total Sales and Production of Rare Earth Elements
8.2 Production of Rare Earth Elements by Region
8.2.1 Current Operational Mines
8.2.1.1 Bayan Obo, China
8.2.1.2 Longnan, China
8.2.1.3 Xunwu, China
8.2.1.4 India
8.2.1.5 Eastern Coast, Brazil
8.2.1.6 Lahat, Malaysia
8.2.1.7 Mt. Weld, Australia
8.2.1.8 Mountain Pass, United States
8.2.1.9 Nolans, Australia
8.2.1.10 Steenkampskraal, South Africa
8.2.1.11 Kvanefjeld, Greenland
8.2.1.12 Dong Pao, Vietnam
8.2.1.13 Dubbo Zirconia, Australia
8.2.2 Potential Operational Mines
8.2.2.1 Nechalacho, Canada
8.3 Consumption of Rare Earth Elements by Region
8.3.1 China
8.3.2 Japan & Northeast Asia
8.3.3 United States
9 Supply & Demand of Individual Rare Earth Elements
9.1 Elements that will Face Supply Shortages in the Near Future
9.1.1 Praseodymium
9.1.1.1 Elements Overview & Supply Risks
9.1.1.2 Supply & Demand
9.1.2 Neodymium
9.1.2.1 Elements Overview & Supply Risks
9.1.2.2 Supply & Demand
9.2 Elements that be Oversupplied in the Near Future
9.2.1 Terbium
9.2.1.1 Elements Overview & Supply Risks
9.2.1.2 Supply & Demand
9.2.2 Yttrium
9.2.2.1 Elements Overview & Supply Risks
9.2.2.2 Supply & Demand
9.2.3 Lanthanum
9.2.3.1 Elements Overview & Supply Risks
9.2.3.2 Supply & Demand
9.2.4 Cerium
9.2.4.1 Elements Overview & Supply Risks
9.2.4.2 Supply & Demand
9.2.5 Dysprosium
9.2.5.1 Elements Overview & Supply Risks
9.2.5.2 Supply & Demand
9.2.6 Samarium
9.2.6.1 Elements Overview & Supply Risks
9.2.6.2 Supply & Demand
9.2.7 Europium
9.2.7.1 Elements Overview & Supply Risks
9.2.7.2 Supply & Demand
10 Market by Application
10.1 Magnets
10.2 NiMH Batteries
10.3 Auto Catalysts
10.4 Diesel Engines
10.5 Fluid Cracking Catalyst
10.6 Phosphers
10.7 Glass
10.8 Polishing Powders
10.9 Other Applications
11 Overview on Mining and Processing of Ion-Adsorption Clays
11.1 Current Technologies
11.2 Typical Costs Involved With Processing RE Oxides
12 Overcoming the Potential Shortfalls in Supply
12.1 Stockpiling
12.2 Recycling
12.3 Substitution
12.4 Material Shortfall Strategies by Various Rare Earth Consumers
13 Competitive Landscape
13.1 Market Structure
13.2 Key Players
13.3 Profiles of Key Players
13.3.1 Lynas Corporation Ltd.
13.3.2 Arafura Resources Limited
13.3.3 Great Western Minerals Group Ltd.
13.3.4 Avalon Advanced Materials Inc.
13.3.5 Greenland Minerals Ltd
13.3.6 Alkane Resources Ltd
13.3.7 Neo Performance Materials
13.3.8 Iluka Resource Limited
13.3.9 IREL (India) Limited
13.3.10 Canada Rare Earths Corporation

Figure 1: Periodic Table Showing Rare Earth Elements
Figure 2: Topology of Rare Earth Elements
Figure 3: Global: Rare Earth Metal Reserves by Country (in Million Metric Tons), 2021
Figure 4: Global: Rare Earth Metal Reserves by Country (in %), 2021
Figure 5: Comparative Total Rare Earth Oxide Values of Various Rare Earth Mines
Figure 6: Kvanefjeld Project Capital Cost Estimated Breakdown
Figure 7: Global: Sources of Rare Earth Metals
Figure 8: Flow Chart: Concentration of Rare Earth Ores
Figure 9: Flow Chart: Extraction of Rare Earths from their Concentrated Ores
Figure 10: China & US: Average Labor Costs Per Hour (in US$), 2021
Figure 11: Global: Rare Earth Metals Production (in 000’ Metric Tons), 2016-2021
Figure 12: Global: Rare Earth Metals Market (in Billion US$), 2016-2021
Figure 13: Global: Rare Earth Metals Production Forecast (in 000’ Metric Tons), 2022-2027
Figure 14: Global: Rare Earth Metals Market Forecast (in Billion US$), 2022-2027
Figure 15: Global: Rare Earth Metals Production by Country (in %), 2021
Figure 16: Bayan Obo Rare Earth Mine: Composition of Various Elements (in %)
Figure 17: Longnan Rare Earth Mine: Composition of Various Elements (in %)
Figure 18: Xunwu Rare Earth Mine: Composition of Various Elements (in %)
Figure 19: India Rare Earth Mine: Composition of Various Elements (in %)
Figure 20: Eastern Coast Rare Earth Mine: Composition of Various Elements (in %)
Figure 21: Lahat Rare Earth Mine: Composition of Various Elements (in %)
Figure 22: Mt Weld Rare Earth Mine: Composition of Various Elements (in %)
Figure 23: Mountain Pass Rare Earth Mine: Composition of Various Elements (in %)
Figure 24: Nolans Rare Earth Mine: Composition of Various Elements (in %)
Figure 25: Steenkampskraal Rare Earth Mine: Composition of Various Elements (in %)
Figure 26: Kvanefjeld Rare Earth Mine: Composition of Various Elements (in %)
Figure 27: Dong Pao Rare Earth Mine: Composition of Various Elements (in %)
Figure 28: Dubbo Zirconia Rare Earth Mine: Composition of Various Elements (in %)
Figure 29: Nechalacho Rare Earth Mine: Composition of Various Elements (in %)
Figure 30: Global: Rare Earth Elements Consumption by Region (in %), 2021
Figure 31: Global: Rare Earth Elements Consumption by Region Forecast (in %), 2027
Figure 32: Praseodymium: Supply & Demand Balance (in Metric Tons), 2021
Figure 33: Praseodymium: Historical Prices (in US$/kg), 2016-2021
Figure 34: Praseodymium: Price Forecast (in US$/kg), 2022-2027
Figure 35: Neodymium: Supply & Demand Balance (in Metric Tons), 2021
Figure 36: Neodymium: Historical Prices (in US$/kg), 2016-2021
Figure 37: Neodymium: Price Forecast (in US$/kg), 2022-2027
Figure 38: Terbium: Supply & Demand Balance (in Metric Tons), 2021
Figure 39: Terbium: Historical Prices (in US$/kg), 2016-2021
Figure 40: Terbium: Price Forecast (in US$/kg), 2022-2027
Figure 41: Yttrium: Supply & Demand Balance (in Metric Tons), 2021
Figure 42: Yttrium: Historical Prices (in US$/kg), 2016-2021
Figure 43: Yttrium: Price Forecast (in US$/kg), 2022-2027
Figure 44: Lanthanum: Supply & Demand Balance (in Metric Tons), 2021
Figure 45: Lanthanum: Historical Prices (in US$/kg), 2016-2021
Figure 46: Lanthanum: Price Forecast (in US$/kg), 2022-2027
Figure 47: Cerium: Supply & Demand Balance (in Metric Tons), 2021
Figure 48: Cerium: Historical Prices (in US$/kg), 2016-2021
Figure 49: Cerium: Price Forecast (in US$/kg), 2022-2027
Figure 50: Dysprosium: Supply & Demand Balance (in Metric Tons), 2021
Figure 51: Dysprosium: Historical Prices (in US$/kg), 2016-2021
Figure 52: Dysprosium: Price Forecast (in US$/kg), 2022-2027
Figure 53: Samarium: Supply & Demand Balance (in Metric Tons), 2021
Figure 54: Samarium: Historical Prices (in US$/kg), 2016-2021
Figure 55: Samarium: Price Forecast (in US$/kg), 2022-2027
Figure 56: Europium: Supply & Demand Balance (in Metric Tons), 2021
Figure 57: Europium: Historical Prices (in US$/kg), 2016-2021
Figure 58: Europium: Price Forecast (in US$/kg), 2022-2027
Figure 59: Diesel Particulate Filter