Materials for PEM Fuel Cells 2026-2036: Technologies, Markets, Players: IDTechEx

1. EXECUTIVE SUMMARY AND CONCLUSIONS 1.1. Overview of PEMFCs 1.2. Major components for PEMFCs 1.3. Applications for fuel cells and major players 1.4. BPP: Purpose and form factor 1.5. Materials for BPPs: Graphite vs metal 1.6. BPP manufacturers flow chart 1.7. GDL: Purpose and form factor 1.8. GDL supply chain for FCEV stacks 1.9. Membrane: Purpose and form factor 1.10. Leading modern PFSA membranes – key players & properties 1.11. Ion exchange membrane material benchmarking – PEM fuel cells 1.12. Ongoing concerns with PFAS regulations 1.13. Catalyst: Purpose and form factor 1.14. Trends for fuel cell catalysts 1.15. Key suppliers of catalysts for fuel cells 1.16. Balance of plant for PEM fuel cells 1.17. Overview of market forecasts 1.18. PEM Fuel Cell Market Value (US$ millions) 2026-2036 1.19. Access more with an IDTechEx subscription 2. MARKET FORECASTS 2.1.1. Forecast methodology and assumptions 2.1.2. PEM Fuel Cell Demand by Application (MW) 2023-2036 2.1.3. PEM Fuel Cell Market Value (US$ millions) 2023-2036 2.1.4. Market Forecasts: Bipolar Plates 2.1.5. BPP Demand (millions of units) by Application 2023-2036 2.1.6. BPP Demand (millions of units) by Material 2023-2036 2.1.7. BPP Value (US$ millions) by Material 2023-2036 2.1.8. Market Forecasts: Gas Diffusion Layer 2.1.9. GDL Demand (000s m2) by Application 2023-2036 2.1.10. GDL Value (US$ millions) by Application 2023-2036 2.1.11. GDL Material Demand (metric tonne) 2023-2036 2.2. Market Forecasts: Membrane, Catalyst & CCM 2.2.1. PEM Demand (000s m2) by Application 2023-2036 2.2.2. PEM Value (US$ millions) by Application 2023-2036 2.2.3. Catalyst/PGM Demand (kg) by Application 2023-2036 2.2.4. CCM Value (US$ millions) by Application 2023-2036 3. INTRODUCTION 3.1.1. Introduction to fuel cells 3.1.2. What is a fuel cell? 3.1.3. Overview of PEMFCs 3.1.4. PEMFCs operating principle 3.1.5. Water-gas shift (WGS) & sour shift reactors 3.1.6. PEM electrolyzer vs PEM fuel cell 3.1.7. Major components for PEMFCs 3.1.8. Fuel cell technologies – overview 3.1.9. Comparison of fuel cell technologies 3.1.10. High temperature PEMFC (1) 3.1.11. High temperature PEMFC (2) 3.1.12. What is a Fuel Cell Vehicle? 3.1.13. Attraction of fuel cell vehicles 3.1.14. Mobility applications for fuel cells 3.1.15. PEMFC market players 3.1.16. Chinese PEMFC market players 3.2. Hydrogen Economy 3.2.1. State of the hydrogen market today 3.2.2. Major drivers for hydrogen production & adoption 3.2.3. Key legislation & funding mechanisms driving hydrogen development 3.2.4. European hydrogen market – major developments 3.2.5. European hydrogen market – major setbacks & challenges 3.2.6. US hydrogen market drivers – pre-2025 3.2.7. US hydrogen market challenges – 2024 and 2025 3.2.8. Outlook on the low-carbon hydrogen industry in the US 3.2.9. Outlook on the low-carbon hydrogen industry globally 4. FCEV MARKETS 4.1. What is a Fuel Cell Vehicle? 4.2. Fuel Cell Vehicles as a Part of the Hydrogen Economy 4.3. 30 Years of Fuel Cell Vehicle Prototypes 4.4. System Efficiency Between BEVs and FCEVs 4.5. Fuel Cell Car Models 4.6. Growth, Stagnation, and Fall of Fuel Cell Passenger Cars 4.7. Toyota Mobility Roadmap 4.8. Toyota Mirai 2nd Generation 4.9. Toyota FCEV Goals 2024 and Beyond 4.10. Hyundai Fuel Cell Passenger Car History 4.11. Hyundai NEXO SUV 4.12. Korea Subsidy Incentives from 2021: FCEV push but BEV far ahead 4.13. Honda Discontinue FC-Clarity: Weak Demand 4.14. Honda to Re-enter FCEV Market 4.15. BMW to Produce FCEVs 4.16. Chinese FCEV Cars 4.17. Outlook for Fuel Cell Passenger Cars 4.18. Light Commercial Vehicles Definition 4.19. Fuel Cell LCVs 4.20. IDTechEx’s Outlook on Fuel Cell LCVs 4.21. Truck Weight Definitions 4.22. Battery vs Fuel Cell Trucks: Driving Range 4.23. Fuel Cell Manufacturers Collaboration on FC-Trucks 4.24. Fuel Cells Trucks Outlook 4.25. Fuel Cell Buses – New Markets May Boost Low Sales 4.26. Main Advantages / Disadvantages of Fuel Cell Buses 4.27. Outlook for Fuel Cell Buses 4.28. FCEV vs BEV Market Share in 2045 5. FC TRAIN MARKETS 5.1. Overview of Train Types 5.2. Drivers for Zero-emission Rail 5.3. Fuel Cell Train Overview 5.4. Range Advantage for Fuel Cell Trains 5.5. Fuel Cell Technology Benchmarking for Rail 5.6. Rail Fuel Cell Suppliers 5.7. FC Multiple Unit Overview 5.8. FC Locomotives Overview 5.9. Outlook for Fuel Cell & Electric Trains 6. FC SHIP MARKETS 6.1. Marine Fuel Cells Introduction 6.2. Fuel Cells Technologies for Ships 6.3. Fuel Cell Suppliers: Leaders & Challengers 6.4. Fuel Cell Supplier Market Share 2019-2024 6.5. Fuel Cell Deliveries by Vessel Type 2019-2024 6.6. Policy Drivers for Maritime Fuel Cells 6.7. Outlook for Marine PEM Fuel Cells 7. STATIONARY FC MARKETS 7.1.1. Stationary fuel cell applications 7.1.2. Overview of the stationary fuel cell application market 7.1.3. PEMFC industrial case studies 7.1.4. PEMFC commercial case studies 7.1.5. PEMFC utilities generation case studies 7.1.6. PEMFC telecommunications case studies 7.1.7. Outlook of the stationary fuel cell market 7.2. Stationary PEMFC Players 7.2.1. Overview of the stationary PEMFC market 7.2.2. Acquisitions by major players 7.2.3. Ballard Power Systems Overview 7.2.4. Ballard technologies 7.2.5. Ballard Power stationary fuel cell technology 7.2.6. Ballard Power global manufacturing capabilities and key partners 7.2.7. Plug Power overview 7.2.8. Plug Power technology overview 7.2.9. Plug Power stationary power technology and fuelling 7.2.10. Plug Power customers 7.2.11. PowerCell Group overview 7.2.12. PowerCell Group technologies 7.2.13. PowerCell Group partnerships and agreements 7.2.14. Intelligent Energy overview 7.2.15. Intelligent Energy stationary power technology 7.2.16. Intelligent Energy partnerships 7.2.17. Toshiba overview 7.2.18. Toshiba fuel cell technology 7.2.19. Cummins overview 7.2.20. Accelera by Cummins fuel cell technology 7.2.21. SFC Energy overview 7.2.22. SFC Energy PEMFC technology 8. BIPOLAR PLATES 8.1.1. Purpose of bipolar plate 8.1.2. BPP form factor 8.1.3. Effect of BPP form factor 8.1.4. Bipolar plate assembly (BPA) 8.2. Materials for BPPs 8.2.1. Important material parameters to consider for BPPs 8.2.2. Graphite as a BPP material 8.2.3. Metal as a BPP material 8.2.4. Cost progression of BPAs 8.2.5. Coatings are required for metal BPPs 8.2.6. Coating choices for metal BPPs 8.2.7. Manufacturing methods for BPPs 8.2.8. BPP manufacturers flow chart 8.3. BPP manufacturers 8.3.1. Overview of BPP Suppliers (non-exhaustive list) 8.3.2. Case Study (NC Titanium): Kobe Steel 8.3.3. Case Study (Dual Supply): Dana 8.3.4. Case Study (Graphite): SGL Carbon 8.3.5. Case Study (Graphite Composite): FJ Composite 8.3.6. Case Study (System Supplier): Schuler 8.3.7. Case Study (Laser Etch): SITEC 8.3.8. Micro Precision – Chemical Etching 8.3.9. Switzer – Chemical Etching 8.3.10. Yiangteng 8.3.11. Hongfeng – Graphite 8.3.12. Comparison of graphite BPP suppliers 8.3.13. Ranked comparison of graphite BPPs 8.4. BPP coating specialists 8.4.1. Impact Coatings 8.4.2. Precors 8.5. Latest trends and research for BPPs 8.5.1. Future directions for bipolar plate flow fields 8.5.2. Printed Circuit Board BPPs – Bramble Energy 8.5.3. Latest trends for BPPs 8.5.4. Loop Energy 8.5.5. CoBiP project 8.5.6. Collaborative Approaches to BPP 8.5.7. Early-stage commercial developments for BPPs 8.5.8. Recent academic research for BPPs 8.5.9. Woven mesh for fuel cells 8.5.10. NBC Meshtec 8.5.11. Haver & Boecker 8.5.12. Emerging manufacturing methods 8.5.13. Collaborative Approaches to BPP 9. GAS DIFFUSION LAYERS 9.1.1. Porous transport layer (PTL) & gas diffusion layer (GDL) summary 9.1.2. PTL/GDL characteristics & materials 9.1.3. Typical GDL structure 9.1.4. Cathode GDL: Hydrophobic treatment 9.1.5. Wet vs dry GDL performance 9.1.6. GDL manufacturing process 9.1.7. Cellulosic fiber GDL: No MPL required 9.1.8. Interactions between GDL & catalyst layer 9.1.9. GDL innovation trends 9.1.10. Focus on dual hydrophobic and hydrophilic behaviour 9.2. GDL Supply Chain & Players 9.2.1. GDL supply chain for FCEV stacks 9.2.2. GDL player: SGL Carbon 9.2.3. GDL player: Toray 9.2.4. GDL player: Freudenberg 9.2.5. AvCarb – advancements in GDL designs for fuel cells 9.2.6. Key GDL suppliers 10. MEMBRANES 10.1.1. Purpose of the membrane 10.1.2. Form factor of the membrane 10.1.3. Water management in the fuel cell 10.1.4. Proton exchange membranes – brief history, functions & materials 10.1.5. Key parameters defining PFSA ionomer structure & properties 10.1.6. Important material parameters to consider for the membrane 10.1.7. Overview of factors causing PEM membrane degradation 10.1.8. Historical perspective on membrane manufacturers & key properties 10.1.9. Nafion – the market leading membrane 10.1.10. Chemours’ Nafion properties & grades 10.1.11. Pros & cons of Nafion & PFSA membranes 10.1.12. Proton exchange membrane market landscape 10.1.13. Leading modern PFSA membranes – key players & properties 10.1.14. Comparison of PFSA membrane properties 10.1.15. Ion exchange membrane material benchmarking – PEM fuel cells 10.1.16. Example supply chain for proton exchange membranes – Gore 10.1.17. High-temperature proton exchange membranes 10.1.18. Innovations in PEMFC membranes may influence PEMEL (1) 10.1.19. Innovations in PEMFC membranes may influence PEMEL (2) 10.1.20. Ongoing concerns with PFAS 10.1.21. Hydrocarbons as PEM fuel cell membranes 10.1.22. Alternative PEM materials: Hydrocarbon IEMs 10.1.23. Assessment of hydrocarbon membranes 10.1.24. Benchmarking of Ionomr membrane against incumbent PFAS membrane 10.1.25. Alternative PEM materials: graphene composites 10.2. Production of PFAS membranes 10.2.1. Fluoropolymers in the polymer pyramid 10.2.2. PFSA ionomer design 10.2.3. PFSA membrane extrusion casting process 10.2.4. PFSA membrane solution casting process 10.2.5. Special release membrane for PFSA solution casting process 10.2.6. PFSA membrane dispersion casting process 10.2.7. Melt-blowing PEM manufacturing process – NRC Canada 10.2.8. Improvements to PFSA membranes 10.2.9. Trade-offs in optimizing membrane performance 10.2.10. Improving dimensional and mechanical stability using simultaneous stretching 10.2.11. Reinforced PFAS membranes: Multilayer vs woven membranes 10.2.12. Chemours reinforced Nafion membranes 10.2.13. Gore reinforced SELECT membranes 10.2.14. Reinforcing ion exchange membranes using multilayer co-extrusion 10.2.15. Innovation areas for reinforced multilayer IEMs 10.2.16. PFSA composite materials 10.2.17. Graphene composites 10.3. Alternatives to PFAS in ion exchange membranes 10.3.1. PFAS Regulations Affecting PEM Fuel Cells & Electrolyzers 10.3.2. Chemours’ focus on responsible manufacturing of Nafion 10.3.3. Key Parameters Required to Replace PFAS Membranes 10.3.4. Emerging Alternative Membranes 10.3.5. Hydrocarbon membranes are leading competitors to PFAS-containing membranes 10.3.6. Alternative polymer materials for ion exchange membranes 10.3.7. Boron-containing hydrocarbon membranes 10.3.8. Other non-PBI containing ion solvating membranes 10.3.9. Glass-filled cross-linked PEEK for improved membrane stiffness 10.3.10. Bio-based PFSA-free membranes based on cellulose 10.3.11. Inorganic and inorganic-organic hybrid ion exchange membranes 10.3.12. Inorganic membranes: Membrion 10.3.13. Metal-organic frameworks (MOFs) – overview 10.3.14. MOF applications in ion exchange membranes 10.3.15. MOF-based ion exchange membranes are not ready for commercialization 10.3.16. Commercial maturity of PFAS alternatives in ion exchange membranes 11. CATALYSTS 11.1.1. Critical platinum group metals: Introduction 11.1.2. Critical platinum group metals: Supply chain considerations 11.1.3. Global PGM demand and application segmentation 11.1.4. Critical platinum group metals: Applications and recycling rates 11.1.5. Platinum as a catalyst 11.1.6. Influence of carbon black support on Pt/C 11.1.7. Catalyst coated membrane (CCM) 11.1.8. CCM production technologies 11.1.9. CCM production technologies 11.1.10. Comparison of coating processes 11.1.11. Roll-to-roll CCM production processes (1/2) 11.1.12. Roll-to-roll CCM production processes (2/2) 11.1.13. RWTH Aachen & Laufenberg’s research into CCM production 11.1.14. Catalyst ink formulation – key considerations 11.1.15. Typical catalyst coated membrane (CCM) 11.1.16. Targets for reducing loading of catalytic materials in fuel cells 11.1.17. Recycling of the catalyst 11.1.18. Catalyst degradation mechanisms 11.1.19. Overview of trends for catalysts 11.1.20. Increasing catalytic activity – alternative metals 11.1.21. Increasing catalytic activity – form factor 11.1.22. SonoTek – Ultrasonic Deposition 11.1.23. Mebius – Pt Skin over Catalyst Core 11.1.24. Reduction of catalyst poisoning 11.1.25. Reduction of cost of catalyst 11.1.26. Future directions for catalysts 11.2. Key Suppliers of Catalysts 11.2.1. Cataler Corporation 11.2.2. Umicore 11.2.3. Johnson Matthey (Honeywell) 11.2.4. Tanaka, Heraeus and BASF 11.2.5. Newly developed catalysts 12. COMPANY PROFILES 12.1. Alleima: Fuel Cell BPP & Interconnect Materials 12.2. Ames Goldsmith Ceimig: PEMEL/FC Electrocatalysts 12.3. AvCarb 12.4. Ballard Motive Solutions 12.5. Ballard Power Systems 12.6. Ballard Power Systems 12.7. Bramble Energy 12.8. CellMo 12.9. Cummins/Hydrogenics: Hydrogen Fuel Cells 12.10. Dana (Bipolar Plates) 12.11. EKPO Fuel Cell Technologies 12.12. FJ Composite 12.13. Heraeus: Catalysts for the Hydrogen Economy 12.14. Hongfeng Carbon Solutions 12.15. Hydrogenics 12.16. Impact Coatings 12.17. Ionomr Innovations 12.18. Jiangsu Yiangteng 12.19. Johnson Matthey: Blue Hydrogen Solutions 12.20. KnitMesh Technologies: Electrolyzer Electrodes & PTL/GDLs 12.21. Kobelco (Bipolar Plates) 12.22. Plug Power 12.23. Plug Power Inc 12.24. Precision Micro 12.25. Schunk