金屬層積造型的全球市場(2026年～2036年)

全球金屬積層製造市場是先進製造業中最具活力和成長最快的領域之一，其特點是卓越的成長軌跡和技術創新，持續重塑多個產業的工業產能。該市場展現出卓越的韌性和持續擴張。

金屬積層製造市場主要分為三大板塊：硬體、材料和服務，每個板塊都呈現不同的成長模式和市場動態。硬體板塊的收入主要由持續的技術進步和成本削減活動推動。材料板塊已成為成長最快的板塊，這反映了從原型設計到生產應用的轉變以及材料消耗的重複性。服務板塊涵蓋從合約製造到品質保證和認證的方方面面，並呈現穩定成長，凸顯了生態系統日益複雜化和專業化。技術演進體現了一種自然的進步模式，早期方法首先佔領利基市場，然後隨著能力的提升、成本的下降以及客戶信心的增強（這些都體現在已證實的商業成功中），逐漸擴展到更廣泛的細分市場。這種活力為設備製造商開發突破性技術創造了機遇，同時也挑戰現有企業透過持續創新來保持競爭力。

材料消費模式反映了原料品質和供應在市場擴張中的關鍵作用。金屬粉末保持其市場主導地位，而包括高熵合金和金屬基複合材料在內的特殊材料則是快速成長的細分市場，以滿足特定的性能要求。儘管低成本系統的產量有所增長，但鈦合金仍保持最大的市場佔有率，這反映了需要高性能材料的航空航天和醫療應用的持續擴張。

市場正透過多項關鍵指標展現出日益成熟的態勢，包括現有企業透過多元化產品組合和經常性收入來源實現的穩定收入表現、隨著成熟方法被更廣泛地採用，技術整合不斷加強，以及需要穩定品質和供應鏈可靠性的生產導向型應用的出現。隨著設備利用率的提高和製造應用的擴展，材料正逐漸成為最大的收入來源，為粉末製造商和特殊材料供應商創造了巨大的機會。

展望未來，金屬積層製造市場將面臨前所未有的機會和不斷變化的挑戰。成功的因素包括：技術領先以實現競爭差異化；成本優化以實現市場准入；卓越的客戶支援以實現客戶維繫；以及創新投資以實現未來定位。產業發展軌跡表明，由於利用率的提高、技術的成熟以及各行各業商業應用的不斷增加，金屬積層製造將繼續保持強勁成長，使其成為現代製造業的變革力量。

本報告探討了全球金屬增材製造市場，深入洞察了市場動態、技術創新、競爭格局以及塑造金屬增材製造未來在航空航太、汽車、醫療、能源和工業應用領域的成長機會。

目錄

第1章 摘要整理

• 概要
• 市場促進因素與阻礙因素
• 中國的市場
• 國際貿易和關稅
• 技術趨勢
• 金屬製造生態系統的服務提供
• 金屬AM的全球市場的預測(2025年～2036年)
• 金屬層積造型生態系統

第2章 簡介

• 3D列印流程
• 金屬層積造型的招聘
• 市場演進
• 金屬AM市場經營模式
• 金屬印表機的性能

第3章 金屬AM市場分析

• 金屬積層製造印表機市場公司
• 金屬材料/粉末市場公司
• 近期財務表現
• 影響金屬積層製造市場的經濟狀況
• 供應鏈挑戰
• 國際貿易摩擦關稅實施
• 技術版圖
• 雷射PBF硬體市場
• 合金
• 投資與融資
• 市場趨勢
• 3D列印服務機構

第4章 金屬印刷流程

• 金屬印刷技術
• 新的金屬印刷技術

第5章 3D列印用金屬材料

• 金屬粉末
• 其他的金屬原料

第6章 對應的金屬材料

• 合金系統
• 鋁，鋁合金
• 銅，青銅
• 鈷，合金
• 鎳合金
• 貴金屬，合金
• 鋼
• 鈦，合金
• 高熵合金
• 非晶質合金
• 多材料解決方案
• 材料資訊學
• 鎢粉末
• 奈米材料

第7章 金屬3D列印的市場與用途

• 航太，防衛
• 醫療
• 汽車
• 能源，石油、天然氣
• 鐵路，交通
• 礦業，重工業
• 工具，製造
• 建設
• 電子，通訊

第8章 企業簡介(企業92家企業簡介)

第9章 附錄

第10章 參考文獻

The global metal additive manufacturing market represents one of the most dynamic and rapidly expanding sectors within advanced manufacturing, characterized by exceptional growth trajectories and technological innovation that continues to reshape industrial production capabilities across multiple sectors. The market has demonstrated remarkable resilience and sustained expansion.

The metal AM market encompasses three primary segments: hardware, materials, and services, each exhibiting distinct growth patterns and market dynamics. Hardware revenues are driven by continuous technological advancement and cost reduction initiatives. The materials segment emerges as the fastest-growing component, reflecting the shift from prototyping to production applications and the recurring nature of material consumption. Services, encompassing everything from contract manufacturing to quality assurance and certification, demonstrate steady growth, highlighting the increasing sophistication and specialization within the ecosystem. The technology evolution reflects natural progression patterns where early-stage approaches initially capture niche applications before expanding into broader market segments as capabilities improve, costs decrease, and customer confidence develops through proven commercial success. This dynamic creates opportunities for equipment manufacturers developing breakthrough technologies while challenging established players to maintain competitive positioning through continuous innovation.

Material consumption patterns reflect the critical role of feedstock quality and availability in market expansion. Metal powders maintain dominant market position, while specialty materials including high entropy alloys and metal matrix composites represent rapidly growing segments addressing specific performance requirements. Titanium alloys maintain the largest market share by value despite volume growth in lower-cost systems, reflecting continued aerospace and medical application expansion requiring high-performance materials.

The market demonstrates increasing maturation through several key indicators: established players maintaining stable revenue performance through diversified portfolios and recurring revenue streams, technology consolidation as proven approaches gain broader adoption, and the emergence of production-oriented applications requiring consistent quality and supply chain reliability. Materials increasingly represent the largest revenue segment as equipment utilization increases and manufacturing applications expand, creating substantial opportunities for powder producers and specialty material suppliers.

Looking forward, the metal additive manufacturing market faces both unprecedented opportunities and evolving challenges. Success factors include technology leadership for competitive differentiation, cost optimization for market accessibility, customer support excellence for retention, and innovation investment for future positioning. The industry's trajectory suggests continued robust growth driven by expanding applications, technology maturation, and increasing commercial adoption across diverse industrial sectors, positioning metal AM as a transformative force in modern manufacturing.

"The Global Metal Additive Manufacturing Market 2026-2036" represents the most comprehensive and authoritative analysis of the rapidly evolving metal 3D printing industry, providing essential market intelligence for manufacturers, investors, technology developers, and strategic decision-makers navigating this transformative manufacturing sector. This definitive market research report delivers deep insights into market dynamics, technological innovations, competitive landscapes, and growth opportunities that will shape the future of metal additive manufacturing across aerospace, automotive, medical, energy, and industrial applications.

Contents include:

• Metal AM Manufacturing Landscape - Industry structure and ecosystem mapping
• Technology Landscape - Comprehensive technology comparison and market positioning
• Investment Landscape - Funding trends, venture capital activity, and M&A analysis
• Market Drivers and Restraints - Growth catalysts and adoption barriers analysis
• China Market Analysis - Regional dynamics and competitive implications
• International Trade and Tariffs - Global trade impacts and policy implications
• Technology Trends - Innovation directions and emerging capabilities
• Service Provision Ecosystem - Service bureau market and business model evolution
• Global Market Forecasts 2025-2036 - Comprehensive revenue and unit projections
  • Installed base forecasts by technology (units)
  • Hardware revenue forecasts by technology
  • Material forecasts by feedstock type, technology, and alloy
• Industry Ecosystem Analysis - Value chain mapping and key player positioning
• 3D Printing Processes Overview - Technology fundamentals and classification
• Material-Process Compatibility - Technology-material matching analysis
• Metal AM Adoption Patterns - Market penetration and growth trajectories
• Market Evolution - Historical development and maturation trends
• Business Models Analysis - Revenue models and strategic approaches
• Performance Metrics Analysis - Build volume, rate, resolution, and price comparison
• Market Analysis and Industry Dynamics:
  • Recent Financial Performance - Public company analysis and sector health
  • Economic Conditions Impact - Macroeconomic factors affecting market growth
  • Supply Chain Challenges - Materials availability and logistics considerations
  • International Trade Tensions - Tariff impacts and reshoring implications
  • Technology Landscape Evolution - Market share dynamics and competitive positioning
  • Laser PBF Hardware Market - Dominant technology segment analysis
  • Alloy Systems Development - Material innovation and adoption patterns
  • Investment and Funding Analysis - Capital flow trends and strategic investments
• Service Bureau and Contract Manufacturing:
  • Service Bureau Operations - Business models and service offerings
  • Design for Additive Manufacturing (DfAM) - Optimization services and capabilities
  • Industry Challenges - Operational constraints and market barriers
  • Leading Service Providers - Company profiles and competitive analysis
  • Part Manufacturers - Proprietary technology and production capabilities
  • In-house Production Trends - Technology adoption and capability development
• Metal Printing Technologies Analysis:
  • Powder Bed Fusion Technologies
  • Directed Energy Deposition
  • Binder Jetting Technologies
  • Ultrasonic Additive Manufacturing (UAM) - Process characteristics and applications
  • Emerging Technologies
• Materials and Feedstock Analysis:
  • Metal Powder Systems
  • Alternative Feedstock Systems
• Compatible Metal Materials Analysis
• Market Applications and End-User Analysis:
  • Aerospace and Defense Applications
  • Medical and Healthcare Applications
  • Automotive Industry Applications
  • Energy and Oil & Gas Sector
  • Railway and Transportation
  • Mining and Heavy Industry
  • Tooling and Manufacturing
  • Construction Industry
  • Electronics and Communications
  • In-depth profiles of 92 market players. Companies profiled include 3D Spark GmbH, 3D Systems, 3D Architech, 3DEO, 3D4MEC, 3T Additive Manufacturing, 6K Additive, Aconity3D GmbH, ADDere, Addilan, Addimetal, ADDiTEC, AddUp, Additive Industries, Admatec Additive Solutions B.V., AIM3D, Alloyed, Alpha Laser, Amaero Inc., AMCM GmbH, AMFREE, APWORKS, Atomik AM, Aurora Labs, Avimetal Additive, Beehive Industries, Bright Laser Technologies (BLT), Caracol, CharmRay, Colibirum Additive, Constellium, Desktop Metal, Divergent Technologies, Inc., DMG Mori, DN Solutions, Elementum 3D, EOS Gmbh, Eplus3D, Equispheres, Exaddon AG, ExOne, Exponential Technologies, Fabric8 Labs, Farsoon Technologies and more....

TABLE OF CONTENTS

1. EXECUTIVE SUMMARY

• 1.1. Overview
  • 1.1.1. Primary Categories
  • 1.1.2. Metal AM Manufacturing Landscape
  • 1.1.3. Technology Landscape
  • 1.1.4. Investment Landscape
• 1.2. Market Drivers and Restraints
• 1.3. The Market in China
• 1.4. International Trade and Tariffs
• 1.5. Technology Trends
• 1.6. Service Provision in the Metal Manufacturing Ecosystem
• 1.7. Metal AM Global Market Forecasts 2025-2036
  • 1.7.1. Installed base 2025-2036 (Units)
  • 1.7.2. Hardware revenue forecast 2025-2036
  • 1.7.3. Material forecast
    • 1.7.3.1. By feedstock 2025-2036
    • 1.7.3.2. By technology 2025-2036
    • 1.7.3.3. By alloy 2025-2036
• 1.8. The Metal Additive Manufacturing Ecosystem

2. INTRODUCTION

• 2.1. 3D printing processes
  • 2.1.1. Material-Process Compatibility
• 2.2. Metal Additive Manufacturing Adoption
• 2.3. Market Evolution
• 2.4. Metal AM Market Business Models
• 2.5. Metal Printers Performance
  • 2.5.1. Build volume capabilities
  • 2.5.2. Build rate
  • 2.5.3. Z resolution
  • 2.5.4. XY Resolution
  • 2.5.5. Price vs build volume
  • 2.5.6. Price vs build rate
  • 2.5.7. Price vs Z resolution
  • 2.5.8. Build rate vs build volume
  • 2.5.9. Build rate vs Z resolution

3. METAL AM MARKET ANALYSIS

• 3.1. Market Players in Metal AM Printers
• 3.2. Market Players in Metal Materials and Powders
• 3.3. Recent Financial Performance
• 3.4. Economic conditions affecting the Metal AM Market
• 3.5. Supply chain challenges
• 3.6. International trade tensions and tariff implementations
• 3.7. Technology Landscape
• 3.8. Laser PBF Hardware Market
• 3.9. Alloys
• 3.10. Investment and Funding
• 3.11. Market Trends
  • 3.11.1. Affordable 3D printing systems
  • 3.11.2. Large-format laser powder bed fusion systems
  • 3.11.3. Sustainability
  • 3.11.4. Electron beam melting technology
  • 3.11.5. The Metal AM market in China
  • 3.11.6. Development of metal binder jetting technology
  • 3.11.7. Service provision expansion
• 3.12. 3D Printing Service Bureaus
  • 3.12.1. Introduction
  • 3.12.2. Service bureau operations
  • 3.12.3. Design for additive manufacturing (DfAM)
  • 3.12.4. Challenges
  • 3.12.5. Companies
    • 3.12.5.1. Leading metal additive manufacturing service bureaus
    • 3.12.5.2. Part manufacturers
  • 3.12.6. In-house production

4. METAL PRINTING PROCESSES

• 4.1. Metal printing technologies
  • 4.1.1. Powder bed fusion
    • 4.1.1.1. Direct metal laser sintering (DMLS) or selective laser melting (SLM)
      • 4.1.1.1.1. Overview
      • 4.1.1.1.2. Selective Laser Sintering (SLS)
      • 4.1.1.1.3. Selective Laser Melting (SLM)
      • 4.1.1.1.4. Capabilities
      • 4.1.1.1.5. Advantages & Limitations
    • 4.1.1.2. Electron beam melting (EBM)
      • 4.1.1.2.1. Overview
      • 4.1.1.2.2. Specifications and Performance Characteristics
  • 4.1.2. Directed energy deposition
    • 4.1.2.1. Powder (or blown powder)
      • 4.1.2.1.1. Overview
      • 4.1.2.1.2. System Capabilities and Applications
      • 4.1.2.1.3. Advantages & Limitations
    • 4.1.2.2. Wire
      • 4.1.2.2.1. Overview
      • 4.1.2.2.2. Capabilities and Applications
  • 4.1.3. Binder jetting
    • 4.1.3.1. Metal binder jetting
      • 4.1.3.1.1. Overview
      • 4.1.3.1.2. Processing
    • 4.1.3.2. Sand binder jetting
      • 4.1.3.2.1. Overview
      • 4.1.3.2.2. Advantages
      • 4.1.3.2.3. Sintering Optimization
  • 4.1.4. Ultrasonic additive manufacturing (UAM)
    • 4.1.4.1.1. Overview
    • 4.1.4.1.2. Characteristics and Capabilities
    • 4.1.4.1.3. Applications
• 4.2. Emerging metal printing technologies
  • 4.2.1. Material Extrusion
    • 4.2.1.1. Metal-polymer filament (MPFE)
    • 4.2.1.2. Metal-polymer pellet
    • 4.2.1.3. Metal paste
  • 4.2.2. Digital light processing (DLP)
  • 4.2.3. Resin-Based Processes
  • 4.2.4. Material jetting
    • 4.2.4.1. Nanoparticle jetting (NPJ)
    • 4.2.4.2. Liquid metal or magnetohydrodynamic deposition
    • 4.2.4.3. Electrochemical deposition
    • 4.2.4.4. Material jetting

5. METAL MATERIALS FOR 3D PRINTING

• 5.1. Metal powders
  • 5.1.1. Metal AM Feedstocks
  • 5.1.2. Powder morphology
  • 5.1.3. Powder production
    • 5.1.3.1. Atomization
    • 5.1.3.2. Electrolysis
  • 5.1.4. Material compatibility
  • 5.1.5. Powder suppliers
  • 5.1.6. Titanium powder
    • 5.1.6.1. Overview
    • 5.1.6.2. Companies
  • 5.1.7. Recycled titanium feedstocks
  • 5.1.8. Post-processing
  • 5.1.9. Barriers and limitations
• 5.2. Other metal feedstocks
  • 5.2.1. Metal wire feedstocks
  • 5.2.2. Metal-polymer filaments and pellets
  • 5.2.3. Metal-photopolymer resins

6. COMPATIBLE METAL MATERIALS

• 6.1. Alloy Systems
  • 6.1.1. Overview
  • 6.1.2. Properties
• 6.2. Aluminum and aluminum alloys
  • 6.2.1. Overview
  • 6.2.2. Advanced aluminum alloys
  • 6.2.3. Aluminum alloy systems and metal-matrix composites
• 6.3. Copper and bronze
  • 6.3.1. Overview
  • 6.3.2. Copper additive manufacturing
  • 6.3.3. Alloy development strategies
  • 6.3.4. Applications
• 6.4. Cobalt and alloys
• 6.5. Nickel alloy
  • 6.5.1. Inconel 625
  • 6.5.2. Inconel 718
• 6.6. Precious metals and alloys
• 6.7. Steel
  • 6.7.1. Maraging steel 1.2709
  • 6.7.2. 15-5PH stainless steel
  • 6.7.3. 17-4PH stainless steel
  • 6.7.4. 316L stainless steel
• 6.8. Titanium and alloys
• 6.9. High entropy alloys
• 6.10. Amorphous alloys
• 6.11. Multi-material solutions
• 6.12. Materials informatics
• 6.13. Tungsten powder
• 6.14. Nanomaterials

7. METAL 3D PRINTING MARKETS AND APPLICATIONS

• 7.1. Aerospace and Defence
  • 7.1.1. Market overview
  • 7.1.2. Applications
    • 7.1.2.1. Fuel nozzles
    • 7.1.2.2. Propulsion systems
    • 7.1.2.3. Engine components
    • 7.1.2.4. Aircraft structural components
    • 7.1.2.5. Gearboxes
    • 7.1.2.6. Satellites
    • 7.1.2.7. Rockets
    • 7.1.2.8. Thermal management
• 7.2. Medical
  • 7.2.1. Overview
  • 7.2.2. Applications
    • 7.2.2.1. Healthcare
    • 7.2.2.2. Medical Devices
      • 7.2.2.2.1. Titanium alloy systems
      • 7.2.2.2.2. Hip replacement
    • 7.2.2.3. Reconstructive surgery
    • 7.2.2.4. Implants
    • 7.2.2.5. Veterinary applications
    • 7.2.2.6. Dental
• 7.3. Automotive
  • 7.3.1. Overview
  • 7.3.2. Applications
    • 7.3.2.1. Production components
    • 7.3.2.2. High-performance brake caliper
• 7.4. Energy and oil & gas
  • 7.4.1. Overview
  • 7.4.2. Applications
    • 7.4.2.1. Turbine components
    • 7.4.2.2. High-temperature applications
• 7.5. Railway and transportation
  • 7.5.1. Overview
  • 7.5.2. Applications
    • 7.5.2.1. Fleet maintenance
    • 7.5.2.2. Remote operations
• 7.6. Mining and heavy industry
  • 7.6.1. Overview
  • 7.6.2. Applications
    • 7.6.2.1. Mining equipment
    • 7.6.2.2. Remote area applications
• 7.7. Tooling and manufacturing
  • 7.7.1. Overview
  • 7.7.2. Applications
    • 7.7.2.1. Complex tooling
• 7.8. Construction
  • 7.8.1. Overview
  • 7.8.2. Applications
    • 7.8.2.1. Facades
    • 7.8.2.2. Bridges
    • 7.8.2.3. Structural optimization applications
• 7.9. Electronics and communications
  • 7.9.1. Overview
  • 7.9.2. Applications
    • 7.9.2.1. RF antennas
    • 7.9.2.2. Thermal management

8. COMPANY PROFILES (92 company profiles)

9. APPENDIX

• 9.1. Glossary
• 9.2. Scope of report

10. REFERENCES

List of Tables

• Table 1. Primary Categories of Metal Additive Manufacturing
• Table 2. Metal AM Technology Performance
• Table 3. Investment Activity 2024
• Table 4. Metal Additive Manufacturing Growth Drivers and Restraints
• Table 5. Metal Additive Manufacturing Technology Trends
• Table 6. Global Market Forecast Summary 2025-2036 (USD Billions)
• Table 7. Installed Base Forecast by Technology (Units)
• Table 8. Global Hardware Revenue Forecast by Technology (USD Millions)
• Table 9. Global Material Revenue Forecast by Feedstock Type (USD Millions) 2025-2036
• Table 10. Global Materials Forecast by Technology (USD Millions)
• Table 11. Global Material Revenue Forecast by Alloy Category (USD Millions)
• Table 12. Industry Ecosystem Key Players Analysis
• Table 13. Additive Manufacturing Process Categories and Fundamental Characteristics
• Table 14. Material-Process Compatibility Assessment
• Table 15. Value Proposition Analysis Across Application Domains
• Table 16. Metal AM Historical Development Timeline and Characteristics
• Table 17. Business Model Analysis and Comparison
• Table 18. Technology Performance Overview and Comparison
• Table 19. Maximum Build Volume Capabilities and Scaling Characteristics
• Table 20. Build Rate Performance Comparison and Analysis
• Table 21. Z-Resolution Capabilities and Quality Impact
• Table 22. XY Resolution Performance and Applications
• Table 23. Price vs Build Volume Economic Analysis
• Table 24. Price vs Z Resolution Economic Analysis
• Table 25. Build Rate vs Build Volume Performance Matrix
• Table 26. Build Rate vs Z Resolution Trade-off Analysis
• Table 27. Performance Extremes and Boundaries
• Table 28. Metal 3D Printer Companies and Products
• Table 29. Metal Materials and Powder Companies
• Table 30. Public Company Financial Performance 2024
• Table 31. Trade Policy Impact Assessment
• Table 32. Technology Market Share Evolution to 20236
• Table 33. Laser PBF Hardware Market Share
• Table 34. Investment Activity Analysis 2024
• Table 35. Private Funding Evolution 2021-2024
• Table 36. Affordable Metal AM System Categories
• Table 37. Large-format LPBF Capabilities and Applications
• Table 38. Large-format LPBF System Capabilities and Market
• Table 39. Sustainability in Metal AM Materials
• Table 40. Metal AM Service Market Segmentation and Growth Analysis
• Table 41. Service Bureau Categories and Capabilities
• Table 42. Service Bureau Core Functions
• Table 43. Service Bureau Value Proposition Analysis
• Table 44. DfAM Service Capabilities and Customer Benefits
• Table 45. Service Bureau Challenge Categories and Impact
• Table 46. Leading Metal AM Service Bureau Companies
• Table 47. Proprietary Technology Manufacturers Analysis
• Table 48. In-House Production Implementation Factors
• Table 49. Metal AM Technologies Comparison Table
• Table 50. DMLS/SLM System Specifications and Capabilities
• Table 51. EBM Technology Specifications and Performance Characteristics
• Table 52. Powder DED System Capabilities and Applications
• Table 53. Wire DED Technology Comparison and Capabilities
• Table 54. Metal Binder Jetting Process Chain Analysis
• Table 55. Sand Binder Jetting Capabilities and Economics
• Table 56. Binder Jetting Technology Enhancement Areas
• Table 57. UAM Process Characteristics and Capabilities
• Table 58. Emerging Technologies
• Table 59. MPFE System Capabilities and Market Positioning
• Table 60. Metal Pellet Extrusion Development Status
• Table 61. Metal Paste Extrusion Applications and Capabilities
• Table 62. Metal DLP Development Status and Capabilities
• Table 63. NPJ Technology Capabilities and Applications
• Table 64. Liquid Metal Deposition Technology Variants
• Table 65. Electrochemical Deposition Characteristics and Capabilities
• Table 66. Cold Spray Technology Applications and Capabilities
• Table 67. Metal AM Feedstock Options Comparison
• Table 68. Powder Morphology Characteristics and Impact
• Table 69. Metal Powder Production Techniques Comparison
• Table 70. Process Impact on Powder Characteristics
• Table 71. Quality Assessment Parameters
• Table 72. Atomization Technology Comparison and Characteristics
• Table 73. Atomization Process Impact on Powder Characteristics
• Table 74. Electrolytic Powder Production Assessment
• Table 75. Metal-Technology Compatibility Assessment
• Table 76. Metal Powder Suppliers by Category
• Table 77. Suppliers by Atomization Technology Specialization
• Table 78. Main Titanium Powder Suppliers
• Table 79. Secondary Titanium Powder Suppliers
• Table 80. Recycled Titanium Feedstock Options and Characteristics
• Table 81. Post-Processing Operations and Requirements
• Table 82. Powder Utilization Barriers and Impact Assessment
• Table 83. Metal Wire Feedstock Characteristics and Applications
• Table 84. Metal-Polymer Feedstock Systems Comparison
• Table 85. Metal-Photopolymer Resin Development Status
• Table 86. Metal Alloy Categories and Key Characteristics
• Table 87. Aluminum Alloy Portfolio for Additive Manufacturing
• Table 88. Emerging Aluminum Alloy Development Status
• Table 89. Emerging Aluminum Materials Development
• Table 90. Copper Alloy Systems for Additive Manufacturing
• Table 91. Copper AM Technology Development Status
• Table 92. Copper Alloy Development Priorities and Status
• Table 93. Cobalt Alloy Systems for Additive Manufacturing
• Table 94. Precious Metal AM Applications and Characteristics
• Table 95. 15-5PH Stainless Steel Applications and Properties
• Table 96. Titanium Alloys for Additive Manufacturing
• Table 97. High Entropy Alloys for Additive Manufacturing
• Table 98. Amorphous Alloy Systems and Applications
• Table 99. Multi-Material AM Applications and Capabilities
• Table 100.Materials Informatics Implementation Status
• Table 101. Tungsten AM Applications
• Table 102. Nanomaterials in Metal AM Applications
• Table 103. Aerospace Metal AM Application Categories
• Table 104. GE Aviation Expanded AM Applications
• Table 105. Boeing 787 Titanium AM Applications
• Table 106. Satellite AM Applications and Requirements
• Table 107. Medical Titanium Alloy Systems and Applications
• Table 108. Automotive Metal AM Applications
• Table 109. Energy Sector Metal AM Applications
• Table 110. Railway and Transportation Applications
• Table 111. Mining and Heavy Industry Applications
• Table 112. Tooling and Manufacturing Applications
• Table 113. Construction Industry Applications
• Table 114. Electronics and Communications Applications

List of Figures

• Figure 1. Graphical representation of AM processes applicable to metals
• Figure 2. Global Market Forecast Summary 2025-2036 (USD Billions)
• Figure 3. Installed Base Forecast by Technology (Units)
• Figure 4. Global Hardware Revenue Forecast by Technology (USD Millions)
• Figure 5. Global Material Revenue Forecast by Feedstock Type (USD Millions) 2025-2036
• Figure 6. Global Materials Forecast by Technology (USD Millions)
• Figure 7. Global Material Revenue Forecast by Alloy Category (USD Millions).
• Figure 8. Workflow Diagram of Metal Additive Manufacturing
• Figure 9. AM based on Electron Beam Melting
• Figure 10. Metal Additive Manufacturing Technologies
• Figure 11. Schematic of SLS Process
• Figure 12. Selective Laser Melting
• Figure 13. Schematic of binder jetting
• Figure 14. Sheet Lamination AM by UAM technology
• Figure 15. Schematic of extrusion base AM technology
• Figure 16. 3D Systems Metal AM printers
• Figure 17. The AconityTWO from Aconity3D
• Figure 18. The Fusion S LPBF printer (left) paired with its integrated powder handling system
• Figure 19. AddUp Machine
• Figure 20. MetalFab 300 Flex
• Figure 21. ADMAFLEX series
• Figure 22. AL3D-METAL
• Figure 23. BLT 3D printers
• Figure 24. The Studio System's printer (left) and furnace (right)
• Figure 25. EOS M 400 series
• Figure 26. EP-M2050 3D metal printer
• Figure 27. Exaddon CERES Print System
• Figure 28. Grob GMP300
• Figure 29. LUMEX Avance-25
• Figure 30. MX3D's M1 Metal AM System shown in multi-unit configuration
• Figure 31. SLM 500
• Figure 32. One Click Metal products
• Figure 33. pam o2 MC 3D printer
• Figure 34. Print Genius400 XL
• Figure 35. Conflux 1 printer
• Figure 36. RenAM 500
• Figure 37. Alba 500
• Figure 38. Sharebot metalONE
• Figure 39. MYSINT100
• Figure 40. The Sodick LPM325S
• Figure 41. SPEE3D printers
• Figure 42. The TKF1000 System from Titomic
• Figure 43. The AMCELL 8300
• Figure 44. TruPrint 3000
• Figure 45. ValCUn Minerva
• Figure 46. The Sapphire XC
• Figure 47. To the left, the XM200G; to the right, the XM300G
• Figure 48. The X Carmel 5000
• Figure 49. iSLM160