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溶劑冶金的全球市場(2024年~2034年)
市場調查報告書
商品編碼
1329011

溶劑冶金的全球市場(2024年~2034年)

The Global Market for Solvometallurgy 2024-2034
出版日期: | 出版商: Future Markets, Inc. | 英文 114 Pages, 27 Tables, 12 Figures | 訂單完成後即時交付

價格

全球能源和高科技市場對主要礦產和金屬的需求持續成長,包括鈷、鉻、鎵、鍺、石墨、銦、鋰、錳、鉬、鎳、稀土和碲。對中國進口的依賴都至關重要。這些材料對於低碳能源未來的長期可用性和成本而言,到 2050 年可能需要超過 30 億噸新礦物和金屬才能實現全球氣候目標。穩定性極為重要。

與傳統製程相比,溶劑冶金可減少溫室氣體排放、能源使用、廢物產生,並提高金屬回收率,以更低的成本從礦石和廢物流中獲得更高的產量。您可以為實現這一目標做出貢獻。市場發展對於金屬和礦物的開採和回收以滿足未來需求至關重要。

本報告提供全球溶劑冶金市場相關調查分析,提供技術的分析,市場推動因素與課題,市場規模的估計,企業簡介等資訊。

目錄

第1章 調查手法

第2章 用語和定義

第3章 技術分析

  • 概要
  • 其他的流程
  • 使用的動機
  • 主要的技術,材料,流程
    • 比較分析
    • 溶媒開採
    • 生物瀝取
    • 氯化物/氯的浸出
    • 超臨界流體開採
    • 離子液體
    • 直接溶媒開採
    • 堆浸
    • 加壓氧化浸出
    • 微波加熱
    • 超音波輔助浸出
    • 紙漿中的樹脂
    • 電解採取
    • 其他
  • 被加工·抽出的金屬和礦物
    • 稀土元素元素(REE)
    • 黃金

第4章 市場分析

  • 市場現狀
  • 市場參與企業
  • SWOT分析
  • 市場地圖
  • 價值鏈
  • 過去和目前市場規模的估計
    • 總收益(2019年~2022年)
    • 各流程,各技術
    • 各地區
  • 成長的估計與預測
    • 估計收益(2023年~2034年)
    • 各流程,各技術
    • 各地區
  • 市場促進因素和成長要素
  • 市場課題

第5章 企業簡介(38家簡介)

第6章 參考材料

Solvometallurgy involves the use of solvents other than water for mineral processing and metal extraction. It can provide environmental and economic benefits compared to traditional processes like pyrometallurgy. With ever increasing global demand from energy and high-tech markets for mined critical minerals and metals such as cobalt, chromium, gallium, germanium, graphite, indium, lithium, manganese, molybdenum, nickel, rare earths, and tellurium, the need to both increase supply and reduce dependence on imports from China is of critical importance. Long-term availability and cost stability of these materials is critical for a low-carbon energy future that will potentially require over 3 billion tons of new minerals and metals to achieve global climate goals by 2050.

Solvometallurgy can contribute to lower greenhouse gas emissions, energy use, and waste production compared to traditional processes, improve metal recoveries and achieve higher yields from ores and waste streams, at a lower cost. The development of the global market for solvometallurgy will be crucial for the extraction and recovery of metals and minerals to meet future demand. Players in the market include start-ups, mining companies and chemical producers.

Report contents include:

  • Technology analysis
  • Description of other processes.
  • Market drivers and challenges.
  • Key technologies and processes including:
    • Solvent Extraction.
    • Bioleaching.
    • Chloride/Chlorine Leaching.
    • Supercritical Fluid Extraction.
    • Ionic Liquids.
    • Heap Leaching.
    • Direct Solvent Extraction.
    • Pressure Oxidation Leaching.
    • Microwave Heating.
    • Ultrasound-Assisted Leaching.
    • Resin-in-Pulp.
    • Electrowinning.
    • Advanced materials
      • Metal-Organic Frameworks (MOFs).
      • Deep eutectic solvents.
      • Nanoparticles.
      • Carbon nanotubes.
      • Conductive polymers.
      • Bio-materials.
  • Analysis of Metals and minerals processed and extracted including:
    • Copper.
    • Nickel.
    • Cobalt.
    • Rare Earth Elements (REE).
    • Lithium.
    • Gold.
    • Uranium.
    • Zinc.
    • Manganese.
    • Tantalum.
    • Niobium.
    • Indium.
    • Gallium.
    • Germanium.
    • Antimony.
    • Scandium.
  • Commercial solvometallurgy market analysis:
    • Current state of the market and future outlook.
    • Market players.
    • SWOT analysis.
    • Market map & value chain.
    • Historical and current market size estimates.
  • Profiles of 38 companies. Companies profiled include BacTech, BASF, Berkeley Energia, EnviroMetal Technologies, Metso, PH7, Rio Tinto and Sumitomo Metal Mining.

TABLE OF CONTENTS

1. RESEARCH METHODOLOGY

2. TERMS AND DEFINITIONS

3. TECHNICAL ANALYSIS

  • 3.1. Description
  • 3.2. Other processes
    • 3.2.1. Pyrometallurgy
    • 3.2.2. Hydrometallurgy
    • 3.2.3. Electrometallurgy
    • 3.2.4. Aeriometallurgy
  • 3.3. Motivation for use
  • 3.4. Key technologies, materials and processes
    • 3.4.1. Comparative analysis
    • 3.4.2. Solvent extraction
      • 3.4.2.1. Process description
      • 3.4.2.2. Advantages
      • 3.4.2.3. Challenges
    • 3.4.3. Bioleaching
      • 3.4.3.1. Process description
      • 3.4.3.2. Advantages
      • 3.4.3.3. Challenges
    • 3.4.4. Chloride/Chlorine Leaching
      • 3.4.4.1. Process description
      • 3.4.4.2. Advantages
      • 3.4.4.3. Challenges
    • 3.4.5. Supercritical Fluid Extraction
      • 3.4.5.1. Process description
      • 3.4.5.2. Advantages
      • 3.4.5.3. Challenges
    • 3.4.6. Ionic Liquids
      • 3.4.6.1. Process description
      • 3.4.6.2. Advantages
      • 3.4.6.3. Challenges
    • 3.4.7. Direct Solvent Extraction
      • 3.4.7.1. Process description
      • 3.4.7.2. Advantages
      • 3.4.7.3. Challenges
    • 3.4.8. Heap Leaching
      • 3.4.8.1. Process description
      • 3.4.8.2. Advantages
      • 3.4.8.3. Challenges
    • 3.4.9. Pressure Oxidation Leaching
      • 3.4.9.1. Process description
      • 3.4.9.2. Advantages
      • 3.4.9.3. Challenges
    • 3.4.10. Microwave Heating
      • 3.4.10.1. Process description
      • 3.4.10.2. Advantages
      • 3.4.10.3. Challenges
    • 3.4.11. Ultrasound-Assisted Leaching
      • 3.4.11.1. Process description
      • 3.4.11.2. Advantages
      • 3.4.11.3. Challenges
    • 3.4.12. Resin-in-Pulp
      • 3.4.12.1. Process description
      • 3.4.12.2. Advantages
      • 3.4.12.3. Challenges
    • 3.4.13. Electrowinning
      • 3.4.13.1. Process description
      • 3.4.13.2. Advantages
      • 3.4.13.3. Challenges
    • 3.4.14. Other
      • 3.4.14.1. Metal-Organic Frameworks (MOFs)
      • 3.4.14.2. Deep eutectic solvents
      • 3.4.14.3. Nanoparticles
      • 3.4.14.4. Carbon nanotubes
      • 3.4.14.5. Conductive polymers
      • 3.4.14.6. Bio-materials
  • 3.5. Metals and minerals processed and extracted
    • 3.5.1. Copper
      • 3.5.1.1. Global copper demand and trends
      • 3.5.1.2. Markets and applications
      • 3.5.1.3. Copper extraction and recovery
    • 3.5.2. Nickel
      • 3.5.2.1. Global nickel demand and trends
      • 3.5.2.2. Markets and applications
      • 3.5.2.3. Nickel extraction and recovery
    • 3.5.3. Cobalt
      • 3.5.3.1. Global cobalt demand and trends
      • 3.5.3.2. Markets and applications
      • 3.5.3.3. Cobalt extraction and recovery
    • 3.5.4. Rare Earth Elements (REE)
      • 3.5.4.1. Global Rare Earth Elements demand and trends
      • 3.5.4.2. Markets and applications
      • 3.5.4.3. Rare Earth Elemens extraction and recovery
      • 3.5.4.4. Recovery of REEs from secondary resources
    • 3.5.5. Lithium
      • 3.5.5.1. Global lithium demand and trends
      • 3.5.5.2. Markets and applications
      • 3.5.5.3. Lithium extraction and recovery
    • 3.5.6. Gold
      • 3.5.6.1. Global gold demand and trends
      • 3.5.6.2. Markets and applications
      • 3.5.6.3. Gold extraction and recovery
    • 3.5.7. Uranium
      • 3.5.7.1. Global uranium demand and trends
      • 3.5.7.2. Markets and applications
      • 3.5.7.3. Uranium extraction and recovery
    • 3.5.8. Zinc
      • 3.5.8.1. Global Zinc demand and trends
      • 3.5.8.2. Markets and applications
      • 3.5.8.3. Zinc extraction and recovery
    • 3.5.9. Manganese
      • 3.5.9.1. Global manganese demand and trends
      • 3.5.9.2. Markets and applications
      • 3.5.9.3. Manganese extraction and recovery
    • 3.5.10. Tantalum
      • 3.5.10.1. Global tantalum demand and trends
      • 3.5.10.2. Markets and applications
      • 3.5.10.3. Tantalum extraction and recovery
    • 3.5.11. Niobium
      • 3.5.11.1. Global niobium demand and trends
      • 3.5.11.2. Markets and applications
      • 3.5.11.3. Niobium extraction and recovery
    • 3.5.12. Indium
      • 3.5.12.1. Global indium demand and trends
      • 3.5.12.2. Markets and applications
      • 3.5.12.3. Indium extraction and recovery
    • 3.5.13. Gallium
      • 3.5.13.1. Global gallium demand and trends
      • 3.5.13.2. Markets and applications
      • 3.5.13.3. Gallium extraction and recovery
    • 3.5.14. Germanium
      • 3.5.14.1. Global germanium demand and trends
      • 3.5.14.2. Markets and applications
      • 3.5.14.3. Germanium extraction and recovery
    • 3.5.15. Antimony
      • 3.5.15.1. Global antimony demand and trends
      • 3.5.15.2. Markets and applications
      • 3.5.15.3. Antimony extraction and recovery
    • 3.5.16. Scandium
      • 3.5.16.1. Global scandium demand and trends
      • 3.5.16.2. Markets and applications
      • 3.5.16.3. Scandium extraction and recovery

4. MARKET ANALYSIS

  • 4.1. Current state of the market
  • 4.2. Market players
  • 4.3. SWOT analysis
  • 4.4. Market map
  • 4.5. Value chain
  • 4.6. Historical and current market size estimates
    • 4.6.1. Total revenues 2019-2022
    • 4.6.2. By process and technology
    • 4.6.3. By region
  • 4.7. Growth projections and forecasts
    • 4.7.1. Estimated revenues 2023-2034
    • 4.7.2. By process and technology
    • 4.7.3. By region
  • 4.8. Market drivers and growth factors
  • 4.9. Market challenges

5. COMPANY PROFILES (38 company profiles)

6. REFERENCES

List of Tables

  • Table 1. Comparison of technologies and processes
  • Table 2. Markets and applications: copper
  • Table 3. Markets and applications: nickel
  • Table 4. Markets and applications: cobalt
  • Table 5. Markets and applications: rare earth elements
  • Table 6. Markets and applications: lithium
  • Table 7. Markets and applications: gold
  • Table 8. Markets and applications: uranium
  • Table 9. Markets and applications: zinc
  • Table 10. Markets and applications: manganese
  • Table 11. Markets and applications: tantalum
  • Table 12. Markets and applications: niobium
  • Table 13. Markets and applications: indium
  • Table 14. Markets and applications: gallium
  • Table 15. Markets and applications: germanium
  • Table 16. Markets and applications: antimony
  • Table 17. Markets and applications: scandium
  • Table 18. Market players in solvometallurgy
  • Table 19. Market players in hydrometallurgical processes and technologies
  • Table 20. Global solvometallurgy market revenues, 2019-2022 (millions USD)
  • Table 21. Global solvometallurgy market revenues, 2019-2022, by process and technology (millions USD)
  • Table 22. Global solvometallurgy market revenues, 2019-2022, by region (millions USD)
  • Table 23. Global solvometallurgy market revenues, 2023-2034 (millions USD)
  • Table 24. Global solvometallurgy market revenues, 2023-2034, by process and technology (millions USD)
  • Table 25. Global solvometallurgy market revenues, 2023-2034, by region (millions USD)
  • Table 26. Market drivers and growth factors
  • Table 27. Market challenges in solvometallurgy

List of Figures

  • Figure 1. Different types of metal extraction
  • Figure 2. Solvent extraction (SX) in hydrometallurgy
  • Figure 3. Heap leaching schematic
  • Figure 4. SWOT analysis: solvometallurgy market
  • Figure 5. Market map: solvometallurgy market
  • Figure 6. Solvometallurgy market value chain
  • Figure 7. Global solvometallurgy market revenues, 2019-2022 (millions USD)
  • Figure 8. Global solvometallurgy market revenues, 2019-2022, by technology (millions USD)
  • Figure 9. Global solvometallurgy market revenues, 2019-2022, by region (millions USD)
  • Figure 10. Global solvometallurgy market revenues, 2023-2034 (millions USD)
  • Figure 11. Global solvometallurgy market revenues, 2023-2034, by technology (millions USD)
  • Figure 12. Global solvometallurgy market revenues, 2023-2034, by region (millions USD)