• Manganese Ore S.A. 36%min In Tianjin Port(-1.2)  07-22|Manganese Ore S.A. 37%min In Tianjin Port(-1.2)  07-22|Lithium Iron Phosphate Li 3.9%min Delivered China(-1000)  07-22|Rhenium APR 99.99%min EXW China(130)  07-22|Arsenic Metal 99%min FOB China(-25)  07-22|Manganese Ore S.A. 36%min In Qinzhou Port(-1.2)  07-22|Manganese Ore S.A. 37%min In Qinzhou Port(-1.2)  07-22|Ferro-dysprosium 80% FOB China(-6)  07-22|Ferro-silicon 75%min In warehouse Pittsburgh(-0.03)  07-22|Silicon Metal 98.5%min Delivered US(-0.05)  07-22|Dysprosium Oxide 99.5%min FOB China(-6)  07-22|Bismuth Ingot 99.99%min EXW China(2500)  07-22|Bismuth Oxide 99.9%min EXW China(2500)  07-22|Antimony Ingot 99.65%min In warehouse Rotterdam(500)  07-22
  • World Magnesium Resource Development Research Report 2021

    2023-09-08 15:03:02   【Print】
    Table of Contents
    List of Figures
    List of Tables
    Text


    Table of Contents

    1 Definition
    1.1 Basic Concepts
    1.2 Types of Minerals
    1.3 Content of Minerals
    1.4 World Reserves
    1.4.1 Minerals Reserves
    1.4.2 Metal Reserves
    1.4.2.1 Volume by States
    1.4.2.2 Volume by Types
    1.4.2.2.1 Solid Minerals
    1.4.2.2.2 Liquid Minerals
    1.5 Application of Minerals
    2 Production Methods
    2.1 Types of Production Methods
    2.2 Definition of Production Methods
    2.2.1 Electrolytic Processes
    2.2.1.1 Dow Method
    2.2.1.1.1 Description
    2.2.1.1.2 Process
    2.2.1.1.3 Characteristics
    2.2.1.2 IG Farben Method
    2.2.1.2.1 Description
    2.2.1.2.2 Process
    2.2.1.2.3 Characteristics
    2.2.1.3 Magnola Method
    2.2.1.3.1 Description
    2.2.1.3.2 Process
    2.2.1.3.3 Characteristics
    2.2.1.4 Carnallite Method
    2.2.1.4.1 Description
    2.2.1.4.2 Process
    2.2.1.4.3 Characteristics
    2.2.1.5 AMC Method
    2.2.1.5.1 Description
    2.2.1.5.2 Process
    2.2.1.5.3 Characteristics
    2.2.1.6 Norsk Hydro Method
    2.2.1.6.1 Description
    2.2.1.6.2 Process
    2.2.1.6.3 Characteristics
    2.2.2 Thermal Reduction Processes
    2.2.2.1 Pidgeon Method
    2.2.2.1.1 Description
    2.2.2.1.2 Process
    2.2.2.1.3 Characteristics
    2.2.2.2 Bolzano Method
    2.2.2.2.1 Description
    2.2.2.2.2 Process
    2.2.2.2.3 Characteristics
    2.2.2.3 Semi-continuous Method
    2.2.2.3.1 Description
    2.2.2.3.2 Process
    2.2.2.3.3 Characteristics
    2.3 Comparison of Production Methods
    2.3.1 Comparison of Electrolytic and Thermal Reduction Processes
    2.3.2 Comparison of Applied Production Methods
    2.4 Application of Production Methods
    2.4.1 Application Rates of Electrolytic and Thermal Reduction Processes
    2.4.1.1 Application Rates by Capacity
    2.4.1.2 Application Rates by Output
    2.4.1.3 Application Rates by Operation
    2.4.2 Application of Electrolytic Processes
    2.4.2.1 Application Rates
    2.4.2.1.1 By Capacity
    2.4.2.1.2 By Output
    2.4.2.1.3 By Operation
    2.4.2.2 Applied Countries
    2.4.2.3 Applied Companies
    2.4.3 Application of Thermal Reduction Processes
    2.4.3.1 Application Rates
    2.4.3.1.1 By Capacity
    2.4.3.1.2 By Output
    2.4.3.1.3 By Operation
    2.4.3.2 Applied Countries
    2.4.3.3 Applied Companies
    3 Raw Material Consumption
    3.1 Raw Material Consumption of Electrolytic Processes
    3.1.1 China Norsk Hydro Method
    3.1.2 US Carnallity Method
    3.1.3 Israel Carnallity Method
    3.1.4 Russia Carnallite Method
    3.2 Raw Material Consumption of Thermal Reduction Processes
    3.2.1 China Pidgeon Method
    3.2.2 Turkey Pidgeon Method
    3.2.3 Brazil Balzano Method
    4 Standard Specifications
    4.1 China Standard Specifications
    4.1.1 MG9990
    4.1.2 MG9995A
    4.1.3 MG9995B
    4.1.4 MG9998
    4.1.5 MG9999
    4.2 Turkey Standard Specifications
    4.2.1 MG9980
    4.2.2 MG9990
    4.2.3 MG9995
    4.3 Russia Standard Specifications
    4.3.1 MG9980
    4.3.2 MG9990
    4.3.3 MG9995
    4.3.4 MG9998
    5 Product Types
    5.1 Definition of Types
    5.1.1 By Grade
    5.1.2 By Weight
    5.2 Market Share of Types
    5.2.1 By Grade
    5.2.2 By Weight
    5.3 Comparison of Production Methods
    5.3.1 By Grade
    5.3.2 By Weight
    6 Product Applications
    6.1 By Grade
    6.2 By Weight
    7 Role in Industrial Chains
    7.1 Magnesium Powder Industry
    7.2 Magnesium Alloy Industry
    7.3 Magnesium Anode Industry
    7.4 Aluminum Alloy Industry
    8 Value in National Economies
    8.1 Industry Value
    8.2 Industry Employment

    List of Figures

    Figure 1 World Magnesium Content of Major Magnesium Minerals 2020
    Figure 2 World Volume of Major Magnesium Minerals 2020 (100m t)
    Figure 3 World Magnesium Content and Proportion of Solid and Liquid Magnesium Minerals 2020
    Figure 4 World Magnesium Content and Proportion of Solid Magnesium Minerals 2020
    Figure 5 World Magnesium Content and Proportion of Liquid Magnesium Minerals 2020 (100m t)
    Figure 6 World Application of Major Magnesium Minerals by Capacity 2020
    Figure 7 World Dow Method Flowchart of Magnesium Production 2020
    Figure 8 World IG Farben Method Flowchart of Magnesium Production 2020
    Figure 9 World Magnola Method Flowchart of Magnesium Production 2020
    Figure 10 World Magnola Method Flowchart of Magnesium Production 2020
    Figure 11 World AMC Method Flowchart of Magnesium Production 2020
    Figure 12 World Norsk Hydro Method Flowchart of Magnesium Production 2020
    Figure 13 World Pidgeon Method Flowchart of Magnesium Production 2020
    Figure 14 World Bolzano Method Flowchart of Magnesium Production 2020
    Figure 15 World Semi-continuous Method Flowchart of Magnesium Production 2020
    Figure 16 World Applied Rates of Electrolytic and Thermal Reduction Processes of Magnesium Production by Capacity 2020
    Figure 17 World Applied Rates of Electrolytic and Thermal Reduction Processes of Magnesium Production by Output 2020
    Figure 18 World Applied Rates of Electrolytic and Thermal Reduction Processes of Magnesium Production by Operation 2020
    Figure 19 World Applied Rates of Electrolytic Processes of Magnesium Production by Capacity 2020
    Figure 20 World Applied Rates of Electrolytic Processes of Magnesium Production by Output 2020 (t)
    Figure 21 World Applied Rates of Electrolytic Processes of Magnesium Production by Operation 2020
    Figure 22 World Applied Rates of Thermal Reduction Processes of Magnesium Production by Capacity 2020 (t)
    Figure 23 World Applied Rates of Thermal Reduction Processes of Magnesium Production by Output 2020
    Figure 24 World Applied Rates of Thermal Reduction Processes of Magnesium Production by Operation 2020
    Figure 25 World Refined Magnesium Output by Grade 2020 (t)
    Figure 26 World Refined Magnesium Output by Weight 2020 (t)
    Figure 27 World Refined Magnesium’s Role in Magnesium Powder Industrial Chain 2020
    Figure 28 World Refined Magnesium’s Role in Magnesium Alloy Industrial Chain 2020
    Figure 29 World Refined Magnesium’s Role in Magnesium Anode Industrial Chain 2020
    Figure 30 World Refined Magnesium’s Role in Aluminum Alloy Industrial Chain 2020
    Figure 31 World Value of Refined Magnesium Industry by Country 2020 (100m USD)
    Figure 32 World Employment of Refined Magnesium Industry by Country 2020 (Person)

    List of Tables

    Table 1 Physical and Chemical Properties of Magnesium
    Table 2 World Types of Major Magnesium Minerals 2020
    Table 3 World Magnesium Content of Major Magnesium Minerals 2020
    Table 4 World Volume of Major Magnesium Minerals 2020 (100m t)
    Table 5 World Magnesium Content and Proportion of Solid and Liquid Magnesium Minerals 2020 (100m t)
    Table 6 World Magnesium Content and Proportion of Solid Magnesium Minerals 2020 (100m t)
    Table 7 World Magnesium Content and Proportion of Liquid Magnesium Minerals 2020 (100m t)
    Table 8 World Application of Major Magnesium Minerals by Capacity 2020 (Mg 10k mt)
    Table 9 World Major Methods and Key Raw Materials of Magnesium Production 2020
    Table 10 World Advantages and Disadvantages of Electrolytic & Thermal Reduction Processes of Magnesium Production 2020
    Table 11 World Advantages and Disadvantages of Major Applied Methods of Magnesium Production 2020
    Table 12 World Applied Rates of Electrolytic and Thermal Reduction Processes of Magnesium Production by Capacity 2020 (t)
    Table 13 World Applied Rates of Electrolytic and Thermal Reduction Processes of Magnesium Production by Output 2020 (t)
    Table 14 World Applied Rates of Electrolytic and Thermal Reduction Processes of Magnesium Production by Operation 2020 (t)
    Table 15 World Applied Rates of Electrolytic Processes of Magnesium Production by Capacity 2020 (t)
    Table 16 World Applied Rates of Electrolytic Processes of Magnesium Production by Output 2020 (t)
    Table 17 World Applied Rates of Electrolytic Processes of Magnesium Production by Operation 2020 (t)
    Table 18 World Applied Countries with Capacity of Electrolytic Processes of Magnesium Production 2020 (t)
    Table 19 World Typical Applied Companies of Electrolytic Processes of Magnesium Production 2020
    Table 20 World Applied Rates of Thermal Reduction Processes of Magnesium Production by Capacity 2020 (t)
    Table 21 World Applied Rates of Thermal Reduction Processes of Magnesium Production by Output 2020 (t)
    Table 22 World Applied Rates of Thermal Reduction Processes of Magnesium Production by Operation 2020 (t)
    Table 23 World Applied Countries with Capacity of Thermal Reduction Processes of Magnesium Production by Country 2020 (t)
    Table 24 World Typical Applied Companies of Thermal Reduction Processes of Magnesium Production 2020
    Table 25 China Raw Material Consumption of Norsk Hydro Method of Magnesium Production 2020 (t)
    Table 26 US Raw Material Consumption of Carnallite Method of Magnesium Production 2020 (t)
    Table 27 Israel Raw Material Consumption of Carnallite Method of Magnesium Production 2020 (t)
    Table 28 Russia Raw Material Consumption of Carnallite Method of Magnesium Production 2020 (t)
    Table 29 China Raw Material Consumption of Pidgeon Method of Magnesium Production 2020 (t)
    Table 30 Turkey Raw Material Consumption of Pidgeon Method of Magnesium Production 2020 (t)
    Table 31 Brazil Raw Material Consumption of Balzano Method of Magnesium Production 2020 (t)
    Table 32 China Standard Specification of Refined Magnesium MG9990 2020
    Table 33 China Standard Specification of Refined Magnesium MG9995A 2020
    Table 34 China Standard Specification of Refined Magnesium MG9995B 2020
    Table 35 China Standard Specification of Refined Magnesium MG9998 2020
    Table 36 China Standard Specification of Refined Magnesium MG9999 2020
    Table 37 Turkey Standard Specification of Refined Magnesium MG9980 2020
    Table 38 Turkey Standard Specification of Refined Magnesium MG9990 2020
    Table 39 Turkey Standard Specification of Refined Magnesium MG9995 2020
    Table 40 Russia Standard Specification of Refined Magnesium MG9980 2020
    Table 41 Russia Standard Specification of Refined Magnesium MG9990 2020
    Table 42 Russia Standard Specification of Refined Magnesium MG9995 2020
    Table 43 Russia Standard Specification of Refined Magnesium MG9998 2020
    Table 44 World Comparison of Types of Refined Magnesium by Content 2020
    Table 45 World Comparison of Types of Refined Magnesium by Weight 2020
    Table 46 World Refined Magnesium Output by Grade 2020 (t)
    Table 47 World Refined Magnesium Output by Weight 2020 (t)
    Table 48 World Magnesium Advantages and Disadvantages by Grade 2020
    Table 49 World Magnesium Advantages and Disadvantages by Weight 2020
    Table 50 World Applications of Refined Magnesium by Grade 2020
    Table 51 World Applications of Refined Magnesium by Weight 2020
    Table 52 World Value of Refined Magnesium Industry by Country 2020 (100m USD)
    Table 53 World Employment of Refined Magnesium Industry by Country 2020 (Person)


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