表紙:高性能エネルギー材料の世界市場(2024年~2035年)
市場調査レポート
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高性能エネルギー材料の世界市場(2024年~2035年)

The Global Market for High-Performance Energetic Materials 2024-2035

出版日: | 発行: Future Markets, Inc. | ページ情報: 英文 176 Pages, 59 Tables, 24 Figures | 納期: 即納可能 即納可能とは

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本日の銀行送金レート: 1GBP=206.60円
高性能エネルギー材料の世界市場(2024年~2035年)
出版日: 2024年06月24日
発行: Future Markets, Inc.
ページ情報: 英文 176 Pages, 59 Tables, 24 Figures
納期: 即納可能 即納可能とは
  • 全表示
  • 概要
  • 図表
  • 目次
概要

当レポートでは、世界の高性能エネルギー材料市場について調査し、市場規模と予測、技術の進歩、各部門における使用状況、将来見通し、企業プロファイルなどの情報を提供しています。

目次

第1章 エグゼクティブサマリー

  • 世界のエネルギー材料市場の概要
  • 高性能エネルギー材料
  • 主な市場動向
  • 成長促進要因
  • 市場の課題
  • バイオベースエネルギー材料

第2章 イントロダクション

  • エネルギー材料の定義と分類
  • 先駆者
  • 高性能エネルギー材料のタイプ
    • RDX
    • HMX
    • CL-20(ヘキサニトロヘキサアザイソウルチタン)
    • TNT(トリニトロトルエン)
    • PETN(四硝酸ペンタエリスリトール)
    • NTO(3-ニトロ-1,2,4-トリアゾール-5-オン)
    • TATB(トリアミノトリニトロベンゼン)
    • FOX-7(1,1-ジアミノ-2,2-ジニトロエテン)
    • ADN(アンモニウムジニトラミド)
    • ANPz(アミノニトロピペラジン)
    • ONC(オクタニトロキュバン)
    • TADA(トリアミノジニトロアゾベンゼン)
  • 製造プロセスと技術

第3章 市場と用途

  • 軍事、防衛
  • 航空宇宙、宇宙探査
  • 鉱業、採石
  • 建設、解体
  • 石油、ガス
  • 花火
  • その他の用途
    • 衝撃波発生装置
    • アディティブマニュファクチャリング
    • 医学研究

第4章 市場の分析

  • 規則
    • 米国
    • 欧州
    • アジア太平洋
  • 価格とコストの分析
    • 市場の価格
  • サプライチェーンと製造
    • エネルギー材料のサプライチェーン
    • 輸出と国内サプライチェーン
  • 競合情勢
    • 市場参入企業
  • 技術の進歩
    • ナノ材料
    • グリーンエナジェティクス
    • 先進の配合
    • 安全性と感受性の研究
    • 先進の合成技術
    • 生物学とバイオエンジニアリングのアプローチ
    • アディティブマニュファクチャリング
    • 理論モデリング、AI、機械学習の進歩
    • 環境にやさしく、無害なエネルギー材料
  • 顧客セグメンテーション
  • 地理的市場
    • 米国
    • 中国
    • インド
    • その他のアジア太平洋
    • オーストラリア
    • ロシア
    • 中東
    • 欧州
    • ラテンアメリカ
  • 獲得可能な市場規模
    • リスクと機会
  • 将来見通し

第5章 企業プロファイル(企業38社のプロファイル)

第6章 調査手法

第7章 参考文献

図表

List of Tables

  • Table 1. Common high-performance energetic materials- properties, advantages, and limitations
  • Table 2. Market trends in energetic materials
  • Table 3. Energetic materials market growth drivers
  • Table 4. Market challenges in energetic materials
  • Table 5. Synthesis methods for RDX
  • Table 6. Global production of RDX, 2022-2035 (Metric Tons)
  • Table 7. Global revenues for RDX, 2022-2035 (Millions USD)
  • Table 8. HMX synthesis methods
  • Table 9. Global production of HMX, 2022-2035 (Metric Tons)
  • Table 10. Global revenues for HMX, 2022-2035 (Millions USD)
  • Table 11. Synthesis Methods for CL-20
  • Table 12. Global production of CL-20, 2022-2035 (Metric Tons)
  • Table 13. Global revenues for CL-20, 2022-2035 (Millions USD)
  • Table 14. Synthesis Methods for TNT
  • Table 15. Global production of TNT, 2022-2035 (Metric Tons)
  • Table 16. Global revenues for TNT, 2022-2035 (Millions USD)
  • Table 17. Synthesis Methods for PETN (Pentaerythritol Tetranitrate)
  • Table 18. Global production of PETN, 2022-2035 (Metric Tons)
  • Table 19. Global revenues for PETN, 2022-2035 (Millions USD)
  • Table 20. Synthesis Methods for NTO
  • Table 21. Global production of NTO, 2022-2035 (Metric Tons)
  • Table 22. Global revenues for NTO, 2022-2035 (Millions USD)
  • Table 23. Synthesis Methods for TATB
  • Table 24. Global production of TATB, 2022-2035 (Metric Tons)
  • Table 25. Global revenues for TATB, 2022-2035 (Millions USD)
  • Table 26. Synthesis Methods for FOX-7 (1,1-Diamino-2,2-dinitroethene)
  • Table 27. Global production of FOX-7, 2022-2035 (Metric Tons)
  • Table 28. Global revenues for FOX-7, 2022-2035 (Millions USD)
  • Table 29. Synthesis Methods for ADN (Ammonium Dinitramide)
  • Table 30. Global production of ADN, 2022-2035 (Metric Tons)
  • Table 31. Global revenues for ADN, 2022-2035 (Millions USD)
  • Table 32. Synthesis Methods for ANPz (Aminonitropiperazine)
  • Table 33. Global production of ANPz, 2022-2035 (Metric Tons)
  • Table 34. Global revenues for ANPz,, 2022-2035 (Millions USD)
  • Table 35. Synthesis Methods for ONC (Octanitrocubane)
  • Table 36. Synthesis Methods for TADA (Triaminodinitroazobenzene)
  • Table 37. Manufacturing processes and technologies for energetic materials-comparative analysis
  • Table 38. Application by energetic material type in military and defense
  • Table 39. High-performance energetic materials in aerospace and space exploration
  • Table 40. Application by energetic material type in mining and quarrying
  • Table 41. Application by energetic material type in construction and demolition
  • Table 42. Application by high-performance energetic material type in oil and gas
  • Table 43. Application by high-performance energetic material type in pyrotechnics
  • Table 44. Properties, Advantages, and Limitations of High-Performance Energetic Materials in Pyrotechnics
  • Table 45. Application by High-Performance Energetic Material Type in Shockwave Generators
  • Table 46. Application by High-Performance Energetic Material Type in Additive Manufacturing
  • Table 47. Application by High-Performance Energetic Material Type in Medical Research
  • Table 48. Market price for common energetic materials ($/lb)
  • Table 49. Market players in high-performance energetic materials in North America
  • Table 50. Market players in high-performance energetic materials in China
  • Table 51. Market players in high-performance energetic materials in Rest of Asia-Pacific
  • Table 52. Market players in high-performance energetic materials in Europe
  • Table 53. Market players in high-performance energetic materials in Rest of the World
  • Table 54. Additive Manufacturing Approaches to High-Performance Energetic Materials
  • Table 55. Theoretical Modeling, Artificial Intelligence (AI), and Machine Learning in Energetic Materials
  • Table 56. Green and Insensitive Energetic Materials
  • Table 57. Comparative analysis of selected energetic materials by primary end user markets
  • Table 58. Addressable market sizes for energetic materials by application (tonnes)
  • Table 59. Future outlook by high-performance energetic materials material type

List of Figures

  • Figure 1. Types of energetic materials
  • Figure 2. Global production of RDX, 2022-2035 (Metric Tons)
  • Figure 3. Global revenues for RDX, 2022-2035 (Millions USD)
  • Figure 4. Global production of HMX, 2022-2035 (Metric Tons)
  • Figure 5. Global revenues for HMX, 2022-2035 (Millions USD)
  • Figure 6. Global production of CL-20, 2022-2035 (Metric Tons)
  • Figure 7. Global revenues for CL-20, 2022-2035 (Millions USD)
  • Figure 8. Global production of TNT, 2022-2035 (Metric Tons)
  • Figure 9. Global revenues for TNT, 2022-2035 (Millions USD)
  • Figure 10. Global production of PETN, 2022-2035 (Metric Tons)
  • Figure 11. Global revenues for PETN, 2022-2035 (Millions USD)
  • Figure 12. Global production of NTO, 2022-2035 (Metric Tons)
  • Figure 13. Global revenues for NTO, 2022-2035 (Millions USD)
  • Figure 14. Global production of TATB, 2022-2035 (Metric Tons)
  • Figure 15. Global revenues for TATB, 2022-2035 (Millions USD)
  • Figure 16. Global production of FOX-7, 2022-2035 (Metric Tons)
  • Figure 17. Global revenues for FOX-7, 2022-2035 (Millions USD)
  • Figure 18. Global production of ADN, 2022-2035 (Metric Tons)
  • Figure 19. Global revenues for ADN, 2022-2035 (Millions USD)
  • Figure 20. Global production of ANPz,, 2022-2035 (Metric Tons)
  • Figure 21. Global revenues for ANPz,, 2022-2035 (Millions USD)
  • Figure 22. Supply chain for energetic materials
  • Figure 23. Typical export supply chain for energetic materials
  • Figure 24. Typical intra-country supply chain for energetic materials
目次

"The Global Market for High-Performance Energetic Materials 2024-2035" provides an in-depth analysis of the evolving energetic materials industry. Energetic materials (EMs), classified as high energy material, explosives, propellants, and pyrotechnic, are compounds capable of rapidly releasing large amounts of energy through controlled chemical reactions.

This comprehensive report covers the key types of energetic materials including RDX, HMX, CL-20, TNT, PETN, NTO, TATB, FOX-7, ADN, ANPz, ONC and TADA. EMs find a wide range of applications both in civil and military sectors. The report examines their classification, manufacturing precursors, and details each major type - describing advantages, disadvantages, production methods, applications and demand factors. A thorough markets and applications analysis is provided, covering military/defense (warheads, ammunition, boosters, detonators, torpedoes, demolition), aerospace (rocket propulsion, gas generators, explosive bolts, airbags), mining, construction/demolition, oil/gas (perforating, well stimulation, exploration), and pyrotechnics (fireworks, flares, tracers). Regulations across the US, Europe, China, Japan, South Korea, Australia, India and Singapore are examined to provide compliance insights. Pricing analysis reveals current market prices for common energetic materials. Supply chain breakdowns detail energetic materials sourcing, manufacturing, exporting and domestic distribution.

Technological advancements are explored including nanomaterials, green energetics, advanced formulations, AI/modeling, additive manufacturing, safety/sensitivity studies, bioengineering approaches, green/insensitive materials, and propulsion system innovations. Customer segmentation analyzes energetic materials usage across military, aerospace, mining, construction, oil/gas, and pyrotechnic sectors. Comprehensive geographic market intelligence covers the US, China, India, Asia-Pacific, Russia, Middle East, Europe and Latin America.

Forecasts are provided for the total addressable market size by application through 2035. Historical data from 2020 quantifies the overall market size (metric tons and $ millions) for key energetic material types like RDX, HMX, CL-20, PETN and others. Projections to 2035 are broken down by type, revenue source and world region.

Risks, opportunities and future outlook considerations round out this definitive energetic materials market report. The competitive landscape is mapped with profiles of leading companies. Companies profiled include BAE Systems, Chemring Nobel, Hanwha Corporation, Island Pyrochemical Industries (IPI), LIG Nex1, Nammo AS, Nitro-Chem SA, Northrop Grumman, Poongsan Corporation, Rheinmetall Defence, Saudi Chemical and main Russian, Chinese and India producers.

TABLE OF CONTENTS

1. EXECUTIVE SUMMARY

  • 1.1. Overview of the global energetic materials market
  • 1.2. High Performance Energetic Materials
  • 1.3. Key market trends
  • 1.4. Growth drivers
  • 1.5. Market Challenges
  • 1.6. Biobased energetic materials

2. INTRODUCTION

  • 2.1. Definition and classification of energetic materials
  • 2.2. Precursors
  • 2.3. Types of high-performance energetic materials
    • 2.3.1. RDX
      • 2.3.1.1. Description and Manufacture
      • 2.3.1.2. Advantages
      • 2.3.1.3. Disadvantages
      • 2.3.1.4. Applications and Market Demand
    • 2.3.2. HMX
      • 2.3.2.1. Description and Manufacture
      • 2.3.2.2. Advantages
      • 2.3.2.3. Disadvantages
      • 2.3.2.4. Applications and Market Demand
    • 2.3.3. CL-20 (Hexanitrohexaazaisowurtzitane)
      • 2.3.3.1. Description and Manufacture
      • 2.3.3.2. Advantages
      • 2.3.3.3. Disadvantages
      • 2.3.3.4. Applications and Market Demand
    • 2.3.4. TNT (Trinitrotoluene)
      • 2.3.4.1. Description and Manufacture
      • 2.3.4.2. Advantages
      • 2.3.4.3. Disadvantages
      • 2.3.4.4. Applications and Market Demand
    • 2.3.5. PETN (Pentaerythritol tetranitrate)
      • 2.3.5.1. Description and Manufacture
      • 2.3.5.2. Advantages
      • 2.3.5.3. Disadvantages
      • 2.3.5.4. Applications and Market Demand
    • 2.3.6. NTO (3-Nitro-1,2,4-triazol-5-one)
      • 2.3.6.1. Description and Manufacture
      • 2.3.6.2. Advantages
      • 2.3.6.3. Disadvantages
      • 2.3.6.4. Applications and Market Demand
    • 2.3.7. TATB (Triaminotrinitrobenzene)
      • 2.3.7.1. Description and Manufacture
      • 2.3.7.2. Advantages
      • 2.3.7.3. Disadvantages
      • 2.3.7.4. Applications and Market Demand
    • 2.3.8. FOX-7 (1,1-Diamino-2,2-dinitroethene)
      • 2.3.8.1. Description and Manufacture
      • 2.3.8.2. Advantages
      • 2.3.8.3. Disadvantages
      • 2.3.8.4. Applications and Market Demand
    • 2.3.9. ADN (Ammonium dinitramide)
      • 2.3.9.1. Description and Manufacture
      • 2.3.9.2. Advantages
      • 2.3.9.3. Disadvantages
      • 2.3.9.4. Applications and Market Demand
    • 2.3.10. ANPz (Aminonitropiperazine)
      • 2.3.10.1. Description and Manufacture
      • 2.3.10.2. Advantages
      • 2.3.10.3. Disadvantages
      • 2.3.10.4. Applications and Market Demand
    • 2.3.11. ONC (Octanitrocubane)
      • 2.3.11.1. Description and Manufacture
      • 2.3.11.2. Advantages
      • 2.3.11.3. Disadvantages
      • 2.3.11.4. Applications and Market Demand
    • 2.3.12. TADA (Triaminodinitroazobenzene)
      • 2.3.12.1. Description and Manufacture
      • 2.3.12.2. Advantages
      • 2.3.12.3. Disadvantages
      • 2.3.12.4. Applications and Market Demand
  • 2.4. Manufacturing processes and technologies

3. MARKETS AND APPLICATIONS

  • 3.1. Military and defense
    • 3.1.1. Overview
    • 3.1.2. Applications
      • 3.1.2.1. Warheads
      • 3.1.2.2. Ammunition
      • 3.1.2.3. Boosters
      • 3.1.2.4. Detonators and Initiators
      • 3.1.2.5. Blasting Caps and Primers
      • 3.1.2.6. Torpedoes and Mines
      • 3.1.2.7. Military Demolition
      • 3.1.2.8. Energetic Composites
      • 3.1.2.9. Unmanned Combat Vehicles and Smaller Weapon Systems
  • 3.2. Aerospace and space exploration
    • 3.2.1. Overview
    • 3.2.2. Applications
      • 3.2.2.1. Rocket Propulsion
      • 3.2.2.2. Gas Generators and Pyrotechnic Devices
      • 3.2.2.3. Explosive Bolts and Separation Mechanisms
      • 3.2.2.4. Airbag Deployment Systems
      • 3.2.2.5. Spacecraft Thrusters
      • 3.2.2.6. Emerging concepts
  • 3.3. Mining and quarrying
    • 3.3.1. Overview
    • 3.3.2. Applications
      • 3.3.2.1. Quarrying
      • 3.3.2.2. Metal Mining
      • 3.3.2.3. Coal Mining
      • 3.3.2.4. Non-Metal Mining
  • 3.4. Construction and demolition
    • 3.4.1. Overview
      • 3.4.1.1. Building Demolition
      • 3.4.1.2. Concrete and Rock Breaking
      • 3.4.1.3. Underwater Demolition
      • 3.4.1.4. Explosive Cutting
      • 3.4.1.5. Blasting Capsules
  • 3.5. Oil and gas
    • 3.5.1. Overview
    • 3.5.2. Applications
      • 3.5.2.1. Oil well perforating charges
      • 3.5.2.2. Oil and Gas Well Stimulation
      • 3.5.2.3. Geophysical Exploration
      • 3.5.2.4. Other
  • 3.6. Pyrotechnics
    • 3.6.1. Overview
    • 3.6.2. Applications
      • 3.6.2.1. Fireworks
      • 3.6.2.2. Signal Flares
      • 3.6.2.3. Explosive Tracers
      • 3.6.2.4. Special Effects
  • 3.7. Other applications
    • 3.7.1. Shockwave Generators
    • 3.7.2. Additive Manufacturing
    • 3.7.3. Medical Research

4. MARKET ANALYSIS

  • 4.1. Regulations
    • 4.1.1. United States
    • 4.1.2. Europe
    • 4.1.3. Asia-Pacific
      • 4.1.3.1. China
      • 4.1.3.2. Japan
      • 4.1.3.3. South Korea
      • 4.1.3.4. Australia
      • 4.1.3.5. India
      • 4.1.3.6. Singapore
  • 4.2. Price and Cost Analysis
    • 4.2.1. Market prices
  • 4.3. Supply Chain and Manufacturing
    • 4.3.1. Supply chain for energetic materials
    • 4.3.2. Export and intra-country supply chains
  • 4.4. Competitive Landscape
    • 4.4.1. Market players
      • 4.4.1.1. North America
      • 4.4.1.2. China
      • 4.4.1.3. Rest of Asia-Pacific
      • 4.4.1.4. Europe
      • 4.4.1.5. Rest of the World
  • 4.5. Technological Advancements
    • 4.5.1. Nanomaterials
    • 4.5.2. Green Energetics
    • 4.5.3. Advanced Formulations
    • 4.5.4. Safety and Sensitivity Studies
    • 4.5.5. Advanced Synthesis Techniques
    • 4.5.6. Biological and Bioengineering Approaches
    • 4.5.7. Additive Manufacturing
    • 4.5.8. Advancements in Theoretical Modeling, Artificial Intelligence (AI), and Machine Learning
    • 4.5.9. Green and Insensitive Energetic Materials
  • 4.6. Customer Segmentation
  • 4.7. Geographical Markets
    • 4.7.1. United States
    • 4.7.2. China
    • 4.7.3. India
    • 4.7.4. Rest of Asia-Pacific
    • 4.7.5. Australia
    • 4.7.6. Russia
    • 4.7.7. Middle East
    • 4.7.8. Europe
    • 4.7.9. Latin America
  • 4.8. Addressable Market Size
    • 4.8.1. Risks and Opportunities
  • 4.9. Future Outlook

5. COMPANY PROFILES (38 company profiles)

6. RESEARCH METHODOLOGY

7. REFERENCES