按应用分類的稀土元素市场报告（磁铁、镍氢电池、汽车催化剂、柴油引擎、流体裂解催化剂、磷光体、玻璃、抛光粉等）和地区 2025-2033

2024年全球稀土元素IMARC Group规模达124亿美元。个人对永续和清洁能源解决方案的日益关注，以及消费性电子产品在全球的广泛使用，主要推动了市场需求。

稀土元素是由 15 种镧系元素以及钪和钇组成的 17 种化学元素。儘管有它们的名字，大多数稀土元素在地壳中并不是特别稀有。它们之所以“稀有”，是因为开采和提炼它们的难度很高。这些元素以其独特的磁性、催化和发光特性而闻名，这使得它们在各种高科技应用中至关重要。它们是各种产品的重要组成部分，从智慧型手机和消费性电子产品到再生能源系统和先进军事技术。

消费性电子、汽车和再生能源等各行业的重大技术创新是推动全球稀土元素市场成长的关键因素之一。稀土元素对于製造电池、磁铁和电子显示器等零件至关重要，这些零件的需求随着技术的进步而不断增长。市场也受到它们在国防应用中的作用的推动，因为这些元素对于生产用于雷达系统、喷气发动机和导弹导引系统的高性能材料至关重要。对绿色能源的日益重视也是一个主要的成长诱导因素。稀土元素对于风力涡轮机和电动车的生产至关重要，符合减少碳排放的全球永续发展目标。此外，地缘政治和贸易关係对市场产生重大影响，因为许多稀土元素供应集中在特定地区，这在供应链中造成了潜在的瓶颈。此外，政府政策，包括使用稀土元素的技术的补贴和战略储备，正在为全球市场创造积极的前景。

稀土元素市场趋势/驱动因素：

重大技术进步

稀土元素需求最有力的驱动因素之一是技术创新的持续步伐。这些元素在众多高科技应用中都是不可或缺的。例如，风力涡轮机中使用的强力磁铁需要钕，而混合动力和电动车电池通常使用镧。除此之外，许多电子设备（例如智慧型手机、平板电脑和笔记型电脑）都含有稀土元素，可实现更小、更有效率的组件。随着这些技术的不断发展和采用率的攀升，对稀土元素的需求不断升级，这进一步推高了市场价值。

不断涌现的绿色能源倡议

环境永续性正成为世界各国政府和组织的焦点，刺激了对清洁能源技术的需求。稀土元素在该领域发挥着至关重要的作用。钕和镝等元素用于生产永久磁铁，这些永久磁铁是风力涡轮机功能不可或缺的一部分。同样，交通运输业电气化的推动也增加了对电池和电动马达中使用的稀土元素的需求。随着各国努力实现雄心勃勃的气候目标并过渡到再生能源，这些元素的市场正在蓬勃发展。

国防应用不断增加

国防应用对稀土元素的需求极大地促进了市场成长。这些要素对于各种先进军事技术来说都是不可或缺的。例如，稀土是製造精确导引弹药、雷达系统和航空电子设备的重要组成部分。它们也用于生产夜视镜和其他光学设备的专用玻璃。随着地缘政治紧张局势升级以及各国在国防能力现代化方面投入更多资金，对稀土元素的需求不断增加。军事对高性能材料的依赖使这些元素成为战略优先事项，通常导致库存和长期采购合约。

全球稀土元素市场细分：

按应用划分：

磁铁

镍氢电池

汽车触媒

柴油引擎

流体裂解催化剂

磷光体

玻璃

抛光粉

其他的

磁铁主导市场

稀土元素，特别是钕、镝和钐，在高性能磁铁的开发中发挥关键作用。这些不是普通的磁铁；它们是磁铁。与传统的铁氧体或铝镍钴磁铁相比，它们具有卓越的磁性。钕磁铁通常与少量镝结合以提高温度稳定性，广泛用于需要坚固、紧凑磁铁的各种应用。在再生能源领域，这些磁铁是风力涡轮发电机的重要部件。它们的高磁力可以实现更有效的能量转换，从而最大限度地提高电力输出。在汽车行业，它们用于电动和混合动力汽车电机，有助于提高功率和效率。这些磁铁在耳机、智慧型手机和硬碟等消费性电子产品中也很常见，它们的小尺寸和高磁场强度在这些电子产品中特别有利。此外，它们对于 MRI 机器等依赖强磁场进行成像的医疗技术至关重要。

按地区划分：

中国

日本及东北亚

美国

中国代表最大的细分市场

该报告还对所有主要区域市场进行了全面分析，包括中国、日本和东北亚以及美国。报告称，中国占最大的市场份额。

中国控制全球稀土元素供应的很大一部分，国内和国际市场的驱动因素有很多。中国电子製造业蓬勃发展，严重依赖稀土元素。作为全球消费性电子产品中心，对这些元件的内部需求很高。中国政府正在实施战略政策来规范和促进稀土产业发展。其中包括出口配额、战略储备和鼓励国内生产的补贴。中国在稀土供应链中的主导地位使其能够影响全球价格和供应。这创造了一个良性循环，吸引了对该国采矿和加工设施的进一步投资。中国正在大力投资再生能源技术，例如风力涡轮机和电动车，这些技术都需要稀土元素。这符合该国雄心勃勃的环境目标。对研究和技术的投资旨在使稀土元素的提取和加工更加高效且环境可持续，从而保持中国的竞争优势。

竞争格局：

在稀土元素市场，主要参与者正在采取一系列策略性倡议，以巩固自己的地位并利用不断增长的需求。这包括对研究和开发的投资，以增强提取技术并提高精炼製程的效率。公司也正在探索伙伴关係和合作，不仅与其他采矿和化学公司，还与科技公司、国防承包商和再生能源提供者等最终用户建立伙伴关係和合作。一些领先企业正在与政府密切合作，以确保稳定的供应链，特别是考虑到围绕稀土元素的地缘政治敏感性。随着公司和国家都致力于降低供应风险，战略库存和长期合约变得越来越普遍。此外，市场领导者正在扩大其地理足迹，以进入新兴市场，这些市场的需求因技术采用和工业成长而不断增长。供应来源多元化也是一项关键策略，旨在减少对特定地区的依赖。

该报告对市场竞争格局进行了全面分析。也提供了所有主要公司的详细资料。市场上的一些主要参与者包括：

莱纳斯有限公司

阿拉弗拉资源有限公司

大西部矿业集团股份有限公司

阿瓦隆先进材料公司

格陵兰矿业股份有限公司

烷烃资源股份有限公司

新功能材料

伊鲁卡资源有限公司

IREL（印度）有限公司

加拿大稀土公司

本报告回答的关键问题

• 2024年全球稀土元素市场规模是多少
• 2025-2033年全球稀土元素市场预计成长率是多少
• COVID-19对全球稀土元素市场有何影响
• 推动全球稀土元素市场的关键因素是什么
• 从应用来看全球稀土元素市场细分如何
• 全球稀土元素市场的重点区域有哪些
• 谁是全球稀土元素市场的主要参与者/公司

本报告回答的关键问题

• 2024年全球稀土市场规模有多大？ 2025-2033年全球稀土元素市场预计成长率是多少？
• COVID-19对全球稀土元素市场有何影响？
• 推动全球稀土元素市场的关键因素是什么？
• 基于应用的全球稀土元素市场区隔如何？
• 全球稀土元素市场的重点区域有哪些？
• 全球稀土元素市场的主要参与者/公司有哪些？

目录

第一章：前言

第 2 章：范围与方法

• 研究目的
• 利害关係人
• 数据来源
  • 主要来源
  • 二手资料
• 市场预测
  • 自下而上的方法
  • 自上而下的方法
• 预测方法

第 3 章：执行摘要

第 4 章：什么是稀土元素？

第 5 章：稀土元素：它们真的很稀有吗？

• 储量估算
• 它们会持续多久？

第 6 章：稀土元素：采矿经济学

• 矿山评估：品位和成分是关键
• 开发新专案：可能需要几年时间
• 稀土开采成本：主要取决于地点和品位开发
• 基础设施和资本成本
• 营运成本
• 重点项目
  • Arafura Resources Limited-Noland项目
  • Nechalacho稀土元素项目
  • Kvanefjeld专案-格陵兰矿产能源有限公司
  • 达博氧化锆-烷烃资源有限公司
• 采矿和加工
  • 矿业
  • 下游加工
• 价格
  • 影响稀土元素价格的因素
  • 历史价格
  • 定价预测

第 7 章：中国在全球稀土元素市场的角色

• 中国对稀土元素具有垄断地位
• 中国的开采成本明显低于其他稀土生产国
• 矿工因缺乏适当的工作标准和环境法规而受益
• 与其他稀土生产国相比，中国拥有明显更高的内部专业知识
• 中国正在策略性地增加生产配额，以维持稀土元素市场的全球主导地位
• 中国的目标是成为高价值商品的出口国

第 8 章：全球稀土元素市场

• 稀土元素销售总量和产量
• 稀土元素产量：按地区
  • 目前营运的矿山
    • 白云鄂博, 中国
    • 中国陇南
    • 寻乌, 中国
    • 印度
    • 巴西东海岸
    • 拉哈, 马来西亚
    • 澳洲韦尔德山
    • 美国帕斯山
    • 澳洲诺兰斯
    • 斯廷坎普斯克拉尔, 南非
    • 格陵兰岛克瓦内菲尔德
    • 越南东宝
    • 澳洲达博氧化锆
  • 潜在营运矿山
    • 加拿大 内查拉乔
• 稀土元素消费量：分地区
  • 中国
  • 日本及东北亚
  • 美国

第 9 章：个别稀土元素的供应与需求

• 近期将面临供应短缺的元素
  • 镨
    • 要素概述与供应风险
    • 供应与需求
  • 钕
    • 要素概述与供应风险
    • 供应与需求
• 近期供应过剩的元素
  • 铽
    • 要素概述与供应风险
    • 供应与需求
  • 钇
    • 要素概述与供应风险
    • 供应与需求
  • 镧
    • 要素概述与供应风险
    • 供应与需求
  • 铈
    • 要素概述与供应风险
    • 供应与需求
  • 鎝
    • 要素概述与供应风险
    • 供应与需求
  • 钹
    • 要素概述与供应风险
    • 供应与需求
  • 铕
    • 要素概述与供应风险
    • 供应与需求

第 10 章：市场：按应用

• 磁铁
• 镍氢电池
• 汽车触媒
• 柴油引擎
• 流体裂解催化剂
• 磷光体
• 玻璃
• 抛光粉
• 其他应用

第 11 章：离子吸附黏土的开采与加工概述

• 目前技术
• 加工稀土氧化物所涉及的典型成本

第 12 章：克服潜在的供应短缺

• 囤货
• 回收
• 替代
• 原料短缺策略：各稀土消费者

第13章：竞争格局

• 市场结构
• 关键参与者
• 关键参与者简介
  • 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

The global rare earth elements market size reached USD 12.4 Billion in 2024. Looking forward, IMARC Group expects the market to reach USD 37.1 Billion by 2033, exhibiting a growth rate (CAGR) of 12.83% during 2025-2033. The rising inclination among individuals towards sustainable and clean energy solutions, along with the widespread usage of consumer electronics across the globe, is primarily propelling the market demand.

Rare earth elements are a group of 17 chemical elements that consist of the 15 lanthanides, along with scandium and yttrium. Despite their name, most rare earth elements are not particularly rare in the Earth's crust. What makes them "rare" is the difficulty associated with mining and refining them. These elements are known for their unique magnetic, catalytic, and luminescent properties, which make them critical in various high-technology applications. They are essential components in a wide array of products, ranging from smartphones and consumer electronics to renewable energy systems and advanced military technologies.

Significant technological innovations across various industries, including consumer electronics, automotive, and renewable energy, represent one of the key factors driving the growth of the rare earth elements market across the globe. Rare earth elements are crucial in manufacturing components like batteries, magnets, and electronic displays, whose demand is rising with technological advancements. The market is also driven by their role in defense applications as these elements are essential in producing high-performance materials used in radar systems, jet engines, and missile guidance systems. The growing emphasis on green energy is also acting as a major growth-inducing factor. Rare earth elements are vital in the production of wind turbines and electric vehicles, aligning with global sustainability goals to reduce carbon emissions. Additionally, geopolitics and trade relations significantly impact the market, as many rare earth element supplies are concentrated in specific regions, which are creating potential bottlenecks in supply chains. Moreover, government policies, including subsidies for technologies that use rare earth elements and strategic stockpiling, are creating a positive outlook for the market across the globe.

Rare Earth Elements Market Trends/Drivers:

Significant technological advancements

One of the most potent drivers of demand for rare earth elements is the relentless pace of technological innovation. These elements are indispensable in a plethora of high-tech applications. For instance, the powerful magnets used in wind turbines require neodymium, while hybrid and electric vehicle batteries often employ lanthanum. In addition to this, many electronic devices, such as smartphones, tablets, and laptops contain rare earth elements that enable smaller, and more efficient components. As these technologies continue to evolve and adoption rates climb, the demand for rare earth elements is escalating, which is further driving up the market value.

Rising green energy initiatives

Environmental sustainability is becoming a focal point for governments and organizations worldwide, stimulating the demand for clean energy technologies. Rare earth elements play a critical role in this sector. Elements like neodymium and dysprosium are used in the production of permanent magnets that are integral to the function of wind turbines. Similarly, the drive for electrification of the transport sector also boosts demand for rare earth elements used in batteries and electric motors. As nations strive to meet ambitious climate targets and transition to renewable energy sources, the market for these elements is fueling.

Rising defense applications

The demand for rare earth elements in defense applications significantly contributes to the market growth. These elements are indispensable for a variety of advanced military technologies. For instance, rare earths are essential components in the manufacturing of precision-guided munitions, radar systems, and avionics. They are also used in the production of specialized glass for night-vision goggles and other optical equipment. As geopolitical tensions escalate and nations invest more in modernizing their defense capabilities, the need for rare earth elements rises. Military reliance on high-performance materials makes these elements a strategic priority, often leading to stockpiling and long-term procurement contracts.

Global Rare Earth Elements Market Segmentation:

Breakup by Application:

Magnets

NiMH Batteries

Auto Catalysts

Diesel Engines

Fluid Cracking Catalyst

Phosphers

Glass

Polishing Powders

Others

Magnets dominate the market

Rare earth elements, particularly neodymium, dysprosium, and samarium, play a critical role in the development of high-performance magnets. These are not ordinary magnets; they offer superior magnetic properties as compared to traditional ferrite or alnico magnets. Neodymium magnets, often combined with small amounts of dysprosium to improve temperature stability, are widely used in a variety of applications requiring strong, compact magnets. In the renewable energy sector, these magnets are essential components in wind turbine generators. Their high magnetic force allows for more efficient energy conversion, thereby maximizing the electrical output. In the automotive industry, they are used in electric and hybrid vehicle motors, contributing to both power and efficiency. These magnets are also prevalent in consumer electronics like headphones, smartphones, and hard disk drives, where their small size and high magnetic strength are particularly beneficial. Additionally, they are crucial in medical technologies such as MRI machines, which rely on strong magnetic fields for imaging.

Breakup by Region:

China

Japan & Northeast Asia

United States

China represents the largest market segment

The report has also provided a comprehensive analysis of all the major regional markets, which include China, Japan & Northeast Asia, and the United States. According to the report, China accounted for the largest market share.

In China, which controls a significant portion of the global supply of rare earth elements, several factors drive the market, both domestically and internationally. China has a booming electronics manufacturing sector that heavily relies on rare earth elements. As a global hub for consumer electronics, the internal demand for these elements is high. The Chinese government is implementing strategic policies to regulate and promote the rare earth industry. These include export quotas, strategic stockpiling, and subsidies to encourage domestic production. China's dominant position in the rare earth supply chain allows it to impact global prices and availability. This creates a virtuous cycle, which is attracting further investment into mining and processing facilities within the country. China is heavily investing in renewable energy technologies, such as wind turbines and electric vehicles, which require rare earth elements. This aligns with the country's ambitious environmental goals. Investments in research and technology aim to make the extraction and processing of rare earth elements more efficient and environmentally sustainable, which is maintaining China's competitive edge.

Competitive Landscape:

In the rare earth elements market, key players are engaging in a range of strategic initiatives to strengthen their position and capitalize on growing demand. This includes investments in research and development to enhance extraction technologies and improve the efficiency of refining processes. Companies are also exploring partnerships and collaborations, not just with other mining and chemical firms, but also with end-users like technology companies, defense contractors, and renewable energy providers. Some leading players are working closely with governments to ensure stable supply chains, especially given the geopolitical sensitivities surrounding rare earth elements. Strategic stockpiling and long-term contracts are becoming more common as both companies and nations aim to mitigate supply risks. Additionally, market leaders are expanding their geographical footprint to tap into emerging markets where demand is rising due to technological adoption and industrial growth. Diversification of supply sources is also a key strategy, aimed at reducing dependence on specific regions.

The report has provided a comprehensive analysis of the competitive landscape in the market. Detailed profiles of all major companies have also been provided. Some of the key players in the market include:

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

Key Questions Answered in This Report

• 1. What was the size of the global rare earth elements market in 2024?
• 2. What is the expected growth rate of the global rare earth elements market during 2025-2033?
• 3. What has been the impact of COVID-19 on the global rare earth elements market?
• 4. What are the key factors driving the global rare earth elements market?
• 5. What is the breakup of the global rare earth elements market based on the application?
• 6. What are the key regions in the global rare earth elements market?
• 7. Who are the key players/companies in the global rare earth elements market?

Table of Contents

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

List of Figures

• 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), 2024
• Figure 4: Global: Rare Earth Metal Reserves by Country (in %), 2024
• 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 USD), 2024
• Figure 11: Global: Rare Earth Metals Production (in 000' Metric Tons), 2019-2024
• Figure 12: Global: Rare Earth Metals Market (in Billion USD), 2019-2024
• Figure 13: Global: Rare Earth Metals Production Forecast (in 000' Metric Tons), 2025-2033
• Figure 14: Global: Rare Earth Metals Market Forecast (in Billion USD), 2025-2033
• Figure 15: Global: Rare Earth Metals Production by Country (in %), 2024
• 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 %), 2024
• Figure 31: Global: Rare Earth Elements Consumption by Region Forecast (in %), 2033
• Figure 32: Praseodymium: Supply & Demand Balance (in Metric Tons), 2024
• Figure 33: Praseodymium: Historical Prices (in USD/kg), 2019-2024
• Figure 34: Praseodymium: Price Forecast (in USD/kg), 2025-2033
• Figure 35: Neodymium: Supply & Demand Balance (in Metric Tons), 2024
• Figure 36: Neodymium: Historical Prices (in USD/kg), 2019-2024
• Figure 37: Neodymium: Price Forecast (in USD/kg), 2025-2033
• Figure 38: Terbium: Supply & Demand Balance (in Metric Tons), 2024
• Figure 39: Terbium: Historical Prices (in USD/kg), 2019-2024
• Figure 40: Terbium: Price Forecast (in USD/kg), 2025-2033
• Figure 41: Yttrium: Supply & Demand Balance (in Metric Tons), 2024
• Figure 42: Yttrium: Historical Prices (in USD/kg), 2019-2024
• Figure 43: Yttrium: Price Forecast (in USD/kg), 2025-2033
• Figure 44: Lanthanum: Supply & Demand Balance (in Metric Tons), 2024
• Figure 45: Lanthanum: Historical Prices (in USD/kg), 2019-2024
• Figure 46: Lanthanum: Price Forecast (in USD/kg), 2025-2033
• Figure 47: Cerium: Supply & Demand Balance (in Metric Tons), 2024
• Figure 48: Cerium: Historical Prices (in USD/kg), 2019-2024
• Figure 49: Cerium: Price Forecast (in USD/kg), 2025-2033
• Figure 50: Dysprosium: Supply & Demand Balance (in Metric Tons), 2024
• Figure 51: Dysprosium: Historical Prices (in USD/kg), 2019-2024
• Figure 52: Dysprosium: Price Forecast (in USD/kg), 2025-2033
• Figure 53: Samarium: Supply & Demand Balance (in Metric Tons), 2024
• Figure 54: Samarium: Historical Prices (in USD/kg), 2019-2024
• Figure 55: Samarium: Price Forecast (in USD/kg), 2025-2033
• Figure 56: Europium: Supply & Demand Balance (in Metric Tons), 2024
• Figure 57: Europium: Historical Prices (in USD/kg), 2019-2024
• Figure 58: Europium: Price Forecast (in USD/kg), 2025-2033
• Figure 59: Diesel Particulate Filter

List of Tables

• Table 1: Rare Earth Elements: Light & Heavy Definitions
• Table 2: Rare Earth Elements: Characteristics & Applications
• Table 3: Light & Heavy Rare Earth Elements: Key Barriers to Entry
• Table 4: Total Time & Stages Required in Constructing & Bringing a Rare Earth Mine to Production
• Table 5: Rare Earth Elements: Mining & Processing Costs
• Table 6: Arafura Resources Limited-Nolans Project: Mining & Production
• Table 7: Arafura Resources Limited-Nolans Project: Financials Involved
• Table 8: Nechalacho Earth Elements Project Capital Cost Summary
• Table 9: Nechalacho Earth Elements Site Capital Cost Summary
• Table 10: Nechalacho Earth Elements Project Operating Cost
• Table 11: Kvanefjeld Project Capital Cost Summary
• Table 12: Kvanefjeld Project Operating Cost Summary
• Table 13: Dubbo Zirconia Project Capital Cost Estimates
• Table 14: Dubbo Zirconia Project Operating Cost Estimates
• Table 15: Sources of Rare Earth Elements & Their Composition
• Table 16: Average Annual Prices of Individual Rare Earth Elements (in USD/Kg), 2019-2024
• Table 17: Average Annual Price Forecast of Individual Rare Earth Elements (in USD/Kg), 2025-2033
• Table 18: China: Rare Earth Elements Production Quota (in Metric Tons), 2019-2024
• Table 19: Global: Distribution of Elements in Various Rare Earth Mines (in %)
• Table 20: Bayan Obo Rare Earth Mine: Composition of Various Elements (in %)
• Table 21: Longnan Rare Earth Mine: Composition of Various Elements (in %)
• Table 22: Xunwu Rare Earth Mine: Composition of Various Elements (in %)
• Table 23: India Rare Earth Mine: Composition of Various Elements (in %)
• Table 24: Eastern Coast Rare Earth Mine: Composition of Various Elements (in %)
• Table 25: Lahat Rare Earth Mine: Composition of Various Elements (in %)
• Table 26: Mt Weld Rare Earth Mine: Composition of Various Elements (in %)
• Table 27: Mountain Pass Rare Earth Mine: Composition of Various Elements (in %)
• Table 28: Nolans Rare Earth Mine: Composition of Various Elements (in %)
• Table 29: Steenkampskraal Rare Earth Mine: Composition of Various Elements (in %)
• Table 30: Kvanefjeld Rare Earth Mine: Composition of Various Elements (in %)
• Table 31: Dong Pao Rare Earth Mine: Composition of Various Elements (in %)
• Table 32: Dubbo Zirconia Rare Earth Mine: Composition of Various Elements (in %)
• Table 33: Nechalacho Rare Earth Mine: Composition of Various Elements (in %)
• Table 34: Global: Rare Earth Elements Consumption by Region & Application (in Metric Tons), 2024
• Table 35: Global: Rare Earth Elements Consumption by Region & Application Forecast (in Metric Tons), 2033
• Table 36: China: Rare Earth Elements Consumption by Application (in Metric Tons), 2024 and 2033
• Table 37: Japan & Northeast Asia: Rare Earth Elements Consumption by Application (in Metric Tons), 2024 and 2033
• Table 38: US: Rare Earth Elements Consumption by Application (in Metric Tons), 2024 and 2033
• Table 39: Global: Supply of Various Rare Earth Elements (in Metric Tons), 2024
• Table 40: Global: Supply & Demand of Various Rare Earth Elements (in Metric Tons), 2024
• Table 41: Praseodymium: Overview, Importance to Clean Energy & Supply Risk
• Table 42: Neodymium: Overview, Importance to Clean Energy & Supply Risk
• Table 43: Terbium: Overview, Importance to Clean Energy & Supply Risk
• Table 44: Yttrium: Overview, Importance to Clean Energy & Supply Risk
• Table 45: Lanthanum: Overview, Importance to Clean Energy & Supply Risk
• Table 46: Cerium: Overview, Importance to Clean Energy & Supply Risk
• Table 47: Dysprosium: Overview, Importance to Clean Energy & Supply Risk
• Table 48: Samarium: Overview, Importance to Clean Energy & Supply Risk
• Table 49: Europium: Overview, Importance to Clean Energy & Supply Risk
• Table 50: Global: Demand of Rare Earth Elements by Application (in Metric Tons), 2019-2024
• Table 51: Global: Demand of Rare Earth Elements by Application (in Metric Tons), 2025-2033
• Table 52: Global: Demand of Rare Earth Elements for Magnets (in Metric Tons), 2019-2024
• Table 53: Global: Demand of Rare Earth Elements for Magnets (in Metric Tons), 2025-2033
• Table 54: Global: Demand of Rare Earth Elements for NiMH Batteries (in Metric Tons), 2019-2024
• Table 55: Global: Demand of Rare Earth Elements for NiMH Batteries (in Metric Tons), 2025-2033
• Table 56: Global: Demand of Rare Earth Elements for Auto Catalysts (in Metric Tons), 2019-2024
• Table 57: Global: Demand of Rare Earth Elements for Auto Catalysts (in Metric Tons), 2025-2033
• Table 58: Global: Demand of Rare Earth Elements for Diesel Engines (in Metric Tons), 2019-2024
• Table 59: Global: Demand of Rare Earth Elements for Diesel Engines (in Metric Tons), 2025-2033
• Table 60: Global: Demand of Rare Earth Elements for FCC (in Metric Tons), 2019-2024
• Table 61: Global: Demand of Rare Earth Elements for FCC (in Metric Tons), 2025-2033
• Table 62: Global: Demand of Rare Earth Elements for Phosphers (in Metric Tons), 2019-2024
• Table 63: Global: Demand of Rare Earth Elements for Phosphers (in Metric Tons), 2025-2033
• Table 64: Global: Demand of Rare Earth Elements for Glass (in Metric Tons), 2019-2024
• Table 65: Global: Demand of Rare Earth Elements for Glass (in Metric Tons), 2025-2033
• Table 66: Global: Demand of Rare Earth Elements for Polishing Powders (in Metric Tons), 2019-2024
• Table 67: Global: Demand of Rare Earth Elements for Polishing Powders (in Metric Tons), 2025-2033
• Table 68: Global: Demand of Rare Earth Elements for Other Applications (in Metric Tons), 2019-2024
• Table 69: Global: Demand of Rare Earth Elements for Other Applications (in Metric Tons), 2025-2033
• Table 70: Rare Earth Elements Processing Costs (USD/lb, TREO)
• Table 71: Mill Operating Costs (USD/lb, TREO)
• Table 72: Extraction/ Separation Plant Operating Costs (USD/lb, TREO)
• Table 73: Substitution Possibilities in Rare Earth Elements
• Table 74: Material Shortfall Strategies by Rare Earth Reserve Rich Countries
• Table 75: Material Shortfall Strategies by Countries Not Having Rich Rare Earth Reserves