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表紙
市場調查報告書

稀土全球市場的應用/技術

Rare Earths: Global Markets, Applications, Technologies

出版商 BCC Research 商品編碼 950817
出版日期 內容資訊 英文 288 Pages
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稀土全球市場的應用/技術 Rare Earths: Global Markets, Applications, Technologies
出版日期: 2020年07月17日內容資訊: 英文 288 Pages
簡介

2019年全球稀土使用量達到2.066億噸。預計在2019年至2023年的預測期內,複合年增長率為9.8%,到2023年將達到3.006億噸。按部門劃分,在預測期內,機械/冶金部門預計將以11.2%的複合年增長率增長,而化學品部門將以10%的複合年增長率增長。

該報告調查了全球稀土市場,並探討了市場規模和預測,政府努力,環境和健康監管見解,專利概況,按地區劃分的產量和預測以及主要參與者。我們提供個人資料等信息。

內容

第1章簡介

第2章執行摘要

第3章市場概述

  • 簡介
  • 稀土歷史和近期事件中的里程碑
  • 專利趨勢:過去,現在和未來
  • 稀土的當前和新用途
  • 稀土化合物和綠色技術的最大機遇
  • 最終用戶行業分析和稀土價值鏈(按行業)
  • 跨地理區域的政府工作
  • 監管框架和政治影響
  • 投資分析
  • 主要市場趨勢
  • 波特的五力分析
  • PESTEL分析

第4章稀土生產技術

  • 簡介
  • 稀土元素的處理
  • 最新技術發展(2012年至今)
  • 世界稀土生產
  • 世界產量匯總

第5章稀土資源的地理分佈

  • 簡介
  • 北美
  • 南美洲
  • 歐洲
  • 非洲
  • 獨立國家共同體(CIS)
  • 亞洲
  • 大洋洲
  • 澳大利亞
  • 世界產量預測
  • 國家產量預測
  • 按要素進行的產量預測

第6章稀土價格

  • 基本稀土氧化物的價格
  • 未來價格趨勢

第7章世界市場

  • 分析概述
  • 世界市場摘要
  • 冶金/機械行業
    • 陶瓷應用
    • 永磁體
    • 按磁體類型劃分的稀土消耗和利潤
    • 冶金合金
  • 玻璃/陶瓷行業
    • 螢光和稀土氧化物
  • 電子,光學,光電子
    • 按元素分列的稀土消費量和利潤
  • 化學領域
  • 能源部門
  • 其他行業

第8章世界業務結構

  • 稀土礦工和供應商
  • 稀土行業的其他主要公司
  • 公司簡介和最新趨勢
  • AGC Seimi Chemical Co.,Ltd.
  • ALUMINUM CORP. OF CHINA
  • ALKANE RESOURCES LTD.
  • ARAFURA RESOURCES
  • ARNOLD MAGNETIC TECHNOLOGIES
  • AVALON ADVANCED MATERIALS INC.
  • CHINA MINMETALS
  • CHINA NORTHERN RARE EARTH HI-TECH CO., LTD.
  • CHINA RARE EARTH HOLDINGS
  • FERRO
  • GANSU RARE EARTH GROUP
  • GANZHOU RARE EARTH GROUP
  • GREENLAND MINERALS LTD.
  • HEXI INDUSTRIAL PARK
  • 日立金屬株式會社
  • HUDSON RESOURCES INC.
  • INDIAN RARE EARTHS
  • IRTYSH RARE EARTHS
  • ILUKA RESOURCES
  • LYNAS CORP.
  • 三井金屬礦業株式會社
  • MOLYCORP
  • NAMIBIA CRITICAL METALS INC.
  • NORTHERN MINERALS LTD.
  • RAINBOW RARE EARTHS
  • RARE ELEMENT RESOURCES LTD.
  • SANTOKU CORP.
  • 信越化學工業株式會社
  • 昭和電工株式會社
  • SOLVAY
  • SUMMIT ATOM RARE EARTH COMPANY
  • TREIBACHER INDUSTRIE
  • UCORE RARE METALS INC.

第9章專利分析

  • 簡介
  • 2015年授予的專利概述
  • 世界專利
  • 美國
  • 歐洲稀土專利
  • 日本專利
  • 總體趨勢
  • 按國家/地區分類的趨勢
  • 趨勢
  • 按專利分類的趨勢
  • 專利申請趨勢
  • 稀土類專利趨勢
  • 按稀土類型劃分的專利趨勢
目錄
Product Code: AVM018J

Highlights:

The global market, in volume terms, for rare earth usage should reach 300.6 million metric tons by 2023 growing from 206.6 million metric tons in 2019, at a compound annual growth rate (CAGR) of 9.8% for the forecast period of 2019 to 2023.

The mechanical/metallurgical segment, in volume terms, of the global rare earth usage market is expected to grow from 81.2 million metric tons in 2019 to 124.2 million metric tons in 2023 at a CAGR of 11.2% for the forecast period of 2019 to 2023.

The chemical segment, in volume terms, of the global rare earth usage market is expected to grow from 31.1 million metric tons in 2019 to 45.5 million metric tons in 2023 at a CAGR of 10.0% for the forecast period of 2019 to 2023.

Report Scope:

This report provides an updated review of rare earth materials, sources, pricing and production processes and identifies current and emerging applications for these materials.

BCC Research delineates the current market status for rare earths, defines trends and presents growth forecasts for the next five years. Supply and sourcing issues, including the latest developments, are also discussed.

The rare earth market is analyzed based on material type and application, and it is expressed as rare earth consumption (in metric tons [t]) and revenues (in $ millions).

A detailed U.S. patent analysis provides further insight regarding market and technological developments.

More specifically, the market analysis conducted by BCC Research for this report is divided into seven sections.

In the first section (Chapter 3), an introduction to the topic and a historical review of rare earth technology are provided, including an outline of recent events. In this section, current and emerging applications for these materials are also identified and divided by sector (e.g., metallurgical/mechanical, chemical, energy and electronics).

The second section (Chapter 4) outlines the latest process developments and improvements related to rare earth production and ends with a summary of global production by country.

The third section (Chapter 5) provides a detailed analysis of the geographical distribution of rare earth sources, discussing the major rare earth mining activities in each country, including supplying an updated assessment of world reserves, a status report on the most important mining projects and global production forecasts.

Past, present and future price trends are presented and discussed in the fourth section (Chapter 6).

Chapter 7 provides a global market analysis of rare earths. Global demand for rare earths is presented by industry/application and by element, with actual data for the years 2019 and estimated data for 2023 Global rare earth revenues by industry are also provided. This analysis of the current rare earth market is followed by a detailed presentation of market growth trends based on industry growth and technological trends. The fifth section concludes by providing projected demand for rare earths within each segment, together with forecast compound annual growth rates (CAGRs) for 2019 through 2023.

  • The sixth section (Chapter 8) of the study, which covers global industry structure, lists rare earth suppliers and descriptions of their products. The analysis includes a description of the geographical distribution of these firms and an evaluation of other key industry players. Detailed company profiles of the top players are also provided.
  • The seventh and final section (Chapter 9) includes an extensive U.S. patent analysis, with a summary of patents related to rare earth materials, processes and applications issued in 2019 Patent analysis is performed by region, country, assignee, patent category, application and material type.

Report Includes:

  • 70 data tables and 41 additional tables
  • An overview of the global market for rare earth elements and description of its current applications
  • Analyses of global market trends, with data corresponding to market size for 2019, estimates from 2020 to 2022, and projections of CAGRs through 2023
  • Details about rare earth compounds and green technology and market share analysis for each of the application
  • Insights into government initiatives across the geographies, regulatory framework, political implications and environmental and health regulations
  • Coverage of novel technologies, R&D progress, market forecast and recent activities in the rare earth element technology
  • Details of mergers & acquisitions, joint ventures, collaborations and agreements and other key market strategies
  • Market share analysis of the key companies of the industry, and their detailed company profiles, including Aluminum Corp. of China, Arnold Magnetic Technologies, Gansu Rare Earth Group, Hitachi Metals Ltd., Indian Rare Earths Ltd., Mitsui Kinzoku, Rare Element Resources Ltd. and Solvay

Table of Contents

Chapter 1 Introduction

  • Study Goals and Objectives
  • Reasons for Doing This Study
  • Intended Audience
  • Scope of Report
  • Methodology and Information Sources
  • Analyst's Credentials
  • BCC Custom Research
  • Related BCC Research Reports

Chapter 2 Executive Summary

Chapter 3 Market Overview

  • Introduction
  • Milestones in the History of Rare Earths and Recent Events
  • Patent Trends: Past, Present and Future
  • Current and Emerging Applications for Rare Earths
  • Metallurgical/Mechanical
  • Glass/Ceramics
  • Electronics, Optics and Optoelectronics
  • Chemical
  • Energy
  • Life Sciences
  • Sensors and Instrumentation
  • Consumer
  • Others
  • Rare Earth Compounds and Green Technology - Biggest Opportunity
  • Novel Technologies and R&D Progress
  • End User Industry Analysis and Rare Earths Value Chain by Industry
  • Electric Vehicles (EV) and Rare Earths
  • Government Initiatives Across Geographic Regions
  • Regulatory Framework and Political Implications
  • Environmental and Health Regulations Impacting the Rare Earth Element Industry
  • Investment Analysis
  • U.S. Army: Investment Analysis for Defense
  • Analysis of Supply Demand for REE (India)
  • Key Market Trends
  • Porter's Five Forces Model
  • Pestel Analysis
  • Political
  • Economic Factors
  • Social Factors
  • Environmental Factors

Chapter 4 Rare Earth Production Technology

  • Introduction
  • Rare Earth Elements Processing
  • Extraction of Rare Earths from Phosphogypsum
  • Metallurgical Process for Recovery of Rare Earth Elements from Low-Grade Ores
  • Mechanochemical Methods for Recovery, Extraction and Separation of Rare Earths
  • Hydrometallurgical Separation of Rare Earth Elements from Uranium-Rich Concentrates
  • Refining Methods for Rare Earths Based on Organic Amine Lixiviants
  • Simplified Metallurgical Treatment for Extraction of Rare Earths
  • Latest Technological Developments, 2012 to Present
  • Organic/Inorganic Composite Containing Rare Earths
  • Transparent Ceramics
  • Bioceramic Coatings Based on Rare Earths
  • Thermoelectric Materials Containing Rare Earths
  • Rare-Earth-Based Magneto-Optical Nanocrystalline Oxides
  • Global Production of Rare Earths
  • Summary of Global Production

Chapter 5 Geographical Distribution of Rare Earth Resources

  • Introduction
  • North America
  • U.S.
  • Canada
  • South America
  • Brazil
  • Argentina
  • Europe
  • Sweden
  • Finland
  • Norway
  • Greenland
  • Africa
  • South Africa
  • Commonwealth of Independent States (CIS)
  • Russia
  • Kyrgyzstan
  • Kazakhstan
  • Asia
  • India
  • China
  • Vietnam
  • Other Asian Resources
  • Oceania
  • Australia
  • Global Production Forecast
  • Production Forecast by Country
  • Production Forecast by Element

Chapter 6 Rare Earth Prices

  • Historical Prices of Basic Rare Earth Oxides
  • Early 1990s to 2003
  • 2003 to 2011
  • Prices 2011 to 2014
  • Future Price Trends
  • China's Production and Export Policies
  • Production Outside China

Chapter 7 Global Markets

  • Outline of Analysis
  • Global Market Summary
  • Market Segmentation by Industry
  • Market Segmentation by Element
  • Metallurgical/Mechanical Sector
  • Ceramics Application
  • Permanent Magnets
  • Consumption and Revenues of Rare Earths by Magnet Type
  • Metallurgical Alloys
  • Glass/Ceramics Sector
  • Fluorescence and Rare Earth Oxides
  • Current Market Summary
  • Market Growth Trends
  • Electronics, Optics and Optoelectronics
  • Current Market Summary
  • Market Growth Trends
  • Market Forecast
  • Consumption and Revenues of Rare Earths by Element
  • Chemical Sector
  • Historic Market Summary
  • Market Forecast
  • Energy Sector
  • Current Market Summary
  • Market Growth Trends
  • Market Forecast
  • Other Sectors
  • Current Market Summary
  • Market Growth Trends
  • Market Forecast

Chapter 8 Global Industry Structure

  • Miners and Suppliers of Rare Earths
  • Other Key Players in the Rare Earth Industry
  • Miners and Suppliers of Rare Earths
  • Company Profiles and Recent Developments
  • AGC SEIMI CHEMICAL
  • ALUMINUM CORP. OF CHINA
  • ALKANE RESOURCES LTD.
  • ARAFURA RESOURCES
  • ARNOLD MAGNETIC TECHNOLOGIES
  • AVALON ADVANCED MATERIALS INC.
  • CHINA MINMETALS
  • CHINA NORTHERN RARE EARTH HI-TECH CO., LTD.
  • CHINA RARE EARTH HOLDINGS
  • FERRO
  • GANSU RARE EARTH GROUP
  • GANZHOU RARE EARTH GROUP
  • GREENLAND MINERALS LTD.
  • HEXI INDUSTRIAL PARK
  • HITACHI METALS LTD.
  • HUDSON RESOURCES INC.
  • INDIAN RARE EARTHS
  • IRTYSH RARE EARTHS
  • ILUKA RESOURCES
  • LYNAS CORP.
  • MITSUI KINZOKU
  • MOLYCORP
  • NAMIBIA CRITICAL METALS INC.
  • NORTHERN MINERALS LTD.
  • RAINBOW RARE EARTHS
  • RARE ELEMENT RESOURCES LTD.
  • SANTOKU CORP.
  • SHIN-ETSU CHEMICAL
  • SHOWA DENKO
  • SOLVAY
  • SUMMIT ATOM RARE EARTH COMPANY
  • TREIBACHER INDUSTRIE
  • UCORE RARE METALS INC.

Chapter 9 Patent Analysis

  • Introduction
  • Summary of Patents Awarded in 2015
  • Global Patents
  • U.S.
  • European Rare Earth-Related Patents
  • European Rare Earth-Related Patents by Specialty
  • European Rare Earth-Related Patents by Key Company
  • European Rare Earth-Related Patents by Key Company and Specialty Segment
  • Japanese Patents
  • Japanese Rare Earth-Related Patents by Specialty
  • Japanese Rare Earth-Related Patents by Key Company
  • Japanese Rare Earth-Related Patents by Key Company and Specialty Segment
  • Historic Analysis of Patent Analysis
  • General Trends
  • Trends by Country and Region
  • Trends by Assignee
  • Trends by Patent Category
  • Patent Trends by Application
  • Patent Trends by Rare Earth Type
  • Patent Trends by Form of Rare Earth

List of Tables

  • Summary Table : Global Market Volumes of Rare Earth Usage, by Industry, Through 2023
  • Table 1 : Lanthanoids
  • Table 2 : Typical Properties of Lanthanoids
  • Table 3 : Scandium and Yttrium
  • Table 4 : Technological and Commercial Milestones in Rare Earth Developments
  • Table 5 : Rare Earth Discoveries
  • Table 6 : Number of Patents Granted to Chinese Companies versus Other Global Companies, 1986-2019
  • Table 7 : Applications of Rare Earths in the Metallurgical and Mechanical Industry, 2014
  • Table 8 : Applications of Rare Earths in the Glass/Ceramics Industry
  • Table 9 : Applications of Rare Earths in Electronics, Optics and Optoelectronics
  • Table 10 : Applications of Rare Earths in the Chemical Industry, 2014
  • Table 11 : Applications of Rare Earths in the Energy Sector, 2014
  • Table 12 : Applications of Rare Earths in the Life Sciences, 2014
  • Table 13 : Applications of Rare Earths in the Sensors and Instrumentation Industry, 2014
  • Table 14 : Applications of Rare Earths in the Consumer Sector, 2014
  • Table 15 : Other Applications of Rare Earths, 2014
  • Table 16 : Basic Processing Steps in the Rare Earth Industry, 2014
  • Table 17 : Rare Earth Reserves, by Country, 2019
  • Table 18 : Mountain Pass, California, U.S.-Typical Ore Composition
  • Table 19 : Iron Hill, Colorado, U.S.-Carbonatite Ore Composition
  • Table 20 : Iron Hill, Colorado, U.S.-Piroxenite Ore Composition
  • Table 21 : Lemhi Pass, Idaho/Montana, U.S.-Typical Ore Composition
  • Table 22 : Elk Creek, Nebraska, U.S.-Typical Ore Composition
  • Table 23 : Round Top Mountain, Texas, U.S.-Typical Ore Composition
  • Table 24 : Bear Lodge, Wyoming, U.S.-Typical Ore Composition
  • Table 25 : Bokan Mountain, Alaska, U.S.-Dotson Ore Composition
  • Table 26 : U.S. Rare Earth Resources
  • Table 27 : Thor Lake, Canada-Nechalacho Ore Composition
  • Table 28 : Eldor, Canada-Ashram Zone Ore Composition
  • Table 29 : Strange Lake, Canada-B-Zone Ore Composition
  • Table 30 : Oka, Canada-Typical Ore Composition
  • Table 31 : Kipawa, Canada-Typical Rare Earth Ore Composition
  • Table 32 : Elliot Lake, Canada-Eco Ridge Rare Earth Ore Composition
  • Table 33 : Hoidas Lake, Canada-Typical Rare Earth Ore Composition
  • Table 34 : Canadian Rare Earth Resources
  • Table 35 : Araxa, Brazil-Typical Rare Earth Ore Composition
  • Table 36 : Catalao, Brazil-Typical Rare Earth Ore Composition
  • Table 37 : Tapira, Brazil-Typical Rare Earth Ore Composition
  • Table 38 : Morro do Ferro, Brazil-Typical Rare Earth Ore Composition
  • Table 39 : Mato Preto, Brazil-Typical Rare Earth Ore Composition
  • Table 40 : Brazilian Rare Earth Resources
  • Table 41 : Norra Karr, Sweden-Typical Rare Earth Ore Composition
  • Table 42 : Olserum, Sweden-Typical Rare Earth Ore Composition
  • Table 43 : Katajakangas, Finland-Typical Rare Earth Ore Composition
  • Table 44 : Kvanefjeld, Greenland Typical Rare Earth Ore Composition
  • Table 45 : Motzfeldt, Greenland-Typical Rare Earth Ore Composition
  • Table 46 : Zandkopsdrift, South Africa-Typical Rare Earth Ore Composition
  • Table 47 : Pilanesberg, South Africa-Typical Rare Earth Ore Composition
  • Table 48 : Steenkampskraal, South Africa-Typical Rare Earth Ore Compositions
  • Table 49 : South African Rare Earth Resources
  • Table 50 : Lovozero, Russia-Typical Rare Earth Ore Composition
  • Table 51 : Khibina, Russia-Typical Rare Earth Ore Composition
  • Table 52 : Russian Rare Earth Resources, 2014
  • Table 53 : Kutessai II, Kyrgyzstan-Typical Rare Earth Ore Composition
  • Table 54 : Kyrgyzstan Rare Earth Resources, 2014
  • Table 55 : India-Typical Monazite Ore Composition
  • Table 56 : Bayan Obo, Inner Mongolia, China-Typical Bastnasite Ore Composition
  • Table 57 : Maoniuping, Sichuan, China-Typical Ore Composition
  • Table 58 : Southern China-Typical Monazite Ore Composition
  • Table 59 : Chinese Rare Earth Resources, 2014
  • Table 60 : Vietnamese Rare Earth Resources, 2014
  • Table 61 : Mt. Weld, Australia-Typical Rare Earth Ore Composition
  • Table 62 : Nolans Bore, Australia-Typical Rare Earth Ore Composition
  • Table 63 : Toongi, Australia-Typical Rare Earth Ore Composition
  • Table 64 : Brockman, Australia-Typical Ore Composition
  • Table 65 : Cummins Range, Australia-Typical Rare Earth Ore Composition
  • Table 66 : Yangibana, Australia-Typical Rare Earth Ore Composition
  • Table 67 : Australian Rare Earth Resources, 2014
  • Table 68 : Rare Earth Production, by Country, 2019-2023
  • Table 69 : Rare Earth Production, by Element, 2019
  • Table 70 : Average Unit Prices of Rare Earths, 99% Purity FOB, 2011-2014
  • Table 71 : Forecast Average Unit Prices of Rare Earths, 99% Purity FOB, Through 2023
  • Table 72 : Global Consumption of Rare Earths, by Industry, Through 2023
  • Table 73 : Global Market for Rare Earth Usage, by Industry, Through 2023
  • Table 74 : Global Consumption of Rare Earths, by Element, 2019-2023
  • Table 75 : Main Types of Permanent Magnets
  • Table 76 : Current Applications for Permanent Magnets
  • Table 77 : Current Rare Earth Magnet Applications
  • Table 78 : Rare Earth Elements for Metallurgy, 2014
  • Table 79 : Global Consumption of Rare Earths for Metallurgy, Through 2023
  • Table 80 : Global Consumption of Rare Earths for Metallurgy, by Element, Through 2023
  • Table 81 : Global Market for Rare Earths for Metallurgy, by Element, Through 2023
  • Table 82 : Rare Earth Elements for Glass and Ceramics, 2019
  • Table 83 : Global Consumption of Rare Earths for Glass and Ceramics, by Application, Through 2023
  • Table 84 : Global Consumption of Rare Earths for Glass and Ceramics, by Element, Through 2023
  • Table 85 : Global Market for Rare Earths for Glass and Ceramics, by Element, Through 2023
  • Table 86 : Rare Earth Elements for Electronics, Optics and Optoelectronics, 2014
  • Table 87 : Global Consumption of Rare Earths for Electronics, Optics and Optoelectronics, by Application, Through 2023
  • Table 88 : Global Consumption of Rare Earths for Electronics, Optics and Optoelectronics, by Element, Through 2023
  • Table 89 : Global Market for Rare Earths for Electronics, Optics and Optoelectronics, by Element, Through 2023
  • Table 90 : Applications of Rare Earth Elements in the Chemical Industry, 2014
  • Table 91 : Global Consumption of Rare Earths in the Chemical Industry, by Application, Through 2023
  • Table 92 : Global Consumption of Rare Earths in the Chemical Industry, by Element, Through 2023
  • Table 93 : Global Market for Rare Earths in the Chemical Industry, by Element, Through 2023
  • Table 94 : Applications of Rare Earth Elements in the Energy Sector, 2014
  • Table 95 : Global Consumption of Rare Earths in the Energy Sector, by Application, Through 2023
  • Table 96 : Global Consumption of Rare Earths in the Energy Sector, by Element, Through 2023
  • Table 97 : Global Market for Rare Earths in the Energy Sector, by Element, Through 2023
  • Table 98 : Applications of Rare Earth Elements in Other Sectors, 2014
  • Table 99 : Global Consumption of Rare Earths in Other Sectors, by Application, Through 2023
  • Table 100 : Global Consumption of Rare Earths in Other Sectors, by Element, Through 2023
  • Table 101 : Global Market for Rare Earths in Other Sectors, by Element, Through 2023
  • Table 102 : Miners and Suppliers of Rare Earths
  • Table 103 : Geographical Distribution of Key Players
  • Table 104 : Other Relevant Industry Players
  • Table 105 : U.S. Rare Earth-Related Patents
  • Table 106 : European Rare Earth-Related Patents
  • Table 107 : Japanese Rare Earth-Related Patents
  • Table 108 : U.S. Rare Earth-Related Patents, 2014
  • Table 109 : Rare Earths U.S. Patent Trends, 2012-2014
  • Table 110 : Assignees of U.S. Rare Earth-Related Patents, 2014

List of Figures

  • Summary Figure : Global Market Volumes of Rare Earth Usage, by Industry, 2019-2023
  • Figure 1 : Rare Earths in the Periodic Table
  • Figure 2 : Number of Patents Granted to Chinese Companies versus Other Global Companies, 1986-2019
  • Figure 3 : Rare Earth Production Share, by Country, 2019
  • Figure 4 : Prices of the Major Rare Earth Oxides, 99% Purity, 1992-2003
  • Figure 5 : Prices of the Major Rare Earth Oxides, 99% Purity FOB, 2003-2011
  • Figure 6 : Global Consumption of Rare Earths, by Industry, 2019-2023
  • Figure 7 : Global Shares of the Consumption of Rare Earths, by Industry, 2019
  • Figure 8 : Industry Shares of Overall Rare Earth Consumption, 2023
  • Figure 9 : Global Shares of the Consumption of Rare Earths, by Element, 2019
  • Figure 10 : Global Shares of the Consumption of Rare Earths, by Element, 2023
  • Figure 11 : Global Shares of the Consumption of Rare Earths for Metallurgy, by Element, 2023
  • Figure 12 : Global Shares of the Consumption of Rare Earths for Glass and Ceramics, by Element, 2023
  • Figure 13 : Global Shares of the Consumption of Rare Earths for Electronics, Optics and Optoelectronics, by Element, 2023
  • Figure 14 : Global Shares of the Consumption of Rare Earths in the Chemical Industry, by Element, 2023
  • Figure 15 : Global Shares of the Consumption of Rare Earths in the Energy Sector, by Element, 2023
  • Figure 16 : Global Shares of the Consumption of Rare Earths in Other Sectors, by Element, 2023
  • Figure 17 : Global Shares of Rare Earth-Related Patents
  • Figure 18 : Shares of U.S. Rare Earth-Related Patents, by Specialty
  • Figure 19 : Shares of U.S. Rare Earth-Related Patents, by Key Company
  • Figure 20 : U.S. Rare Earth-Related Patents, by Key Company and Specialty Area
  • Figure 21 : European Shares of Rare Earth-Related Patents, by Specialty
  • Figure 22 : European Shares of Rare Earth-Related Patents, by Key Company
  • Figure 23 : European Shares of Rare Earth-Related Patents, by Key Company and Specialty Area
  • Figure 24 : Shares of Japanese Rare Earth-Related Patents, by Specialty
  • Figure 25 : Shares of Japanese Rare Earth-Related Patents, by Key Company
  • Figure 26 : Japanese Rare Earth-Related Patents, by Key Company and Specialty Area
  • Figure 27 : Trends in U.S. Rare Earth-Related Patents, 2012-2014
  • Figure 28 : Shares of U.S. Rare Earth-Related Patents, by Region, 2014
  • Figure 29 : Shares of U.S. Rare Earth-Related Patents, by Country, 2014
  • Figure 30 : Shares of U.S. Rare Earth-Related Patents, by Category, 2014
  • Figure 31 : Shares of U.S. Patents on Applications of Rare Earths, 2014
  • Figure 32 : Shares of U.S. Rare Earth-Related Patents, by Material Type, 2014
  • Figure 33 : Shares of U.S. Rare Earth-Related Patents, by Form of Use, 2014