Direct Methanol Fuel Cells Market was valued US$ 240.58 Mn. in 2022 and the total revenue is expected to grow at 12.9% through 2023 to 2029, reaching US$ 562.51 Mn. The report has analyzed revenue impact of COVID -19 pandemic on the sales revenue of market leaders, market followers and market disrupters in the report and same is reflected in our analysis.Direct Methanol Fuel Cells Market Overview
Direct methanol fuel cells i.e. DMFCs is a type of proton exchange fuel cells which adapts the chemical energy of liquid methanol into electrical energy. Developments in DMFCs because it is produced by PEM (Polymer Electrolyte Membrane) owing to their simple construction and the low-temperature process are expected to drive its demand in alternative energy.To know about the Research Methodology :- Request Free Sample Report
Direct Methanol Fuel Cells Market Dynamics
The MMR report contains a detailed study of factors that will drive and restrain the growth of the market. Expanding the market is because of growing R&D investment by companies for commercialization and initiatives of these cells. Direct methanol fuel cells can also be used in vehicles instead of conservative fuel and are considered to be better efficiency and more reliable. These features are presumed to help the worldwide as well as regional DMFCs markets. To encourage product taking across industries and in turn, complement market growth, Direct methanol fuel and subsequent storing of methanol are comparatively easy than other materials. The essential for longer battery life and higher performance and rapidly rising personal electronic product consumption is expected to further strengthen the DMFCs market. In recent years, because of the growing impact of emissions on the environment, government organizations and many companies have been spending heavily in the fuel cell technology to develop technically and financially feasible fuel cells. Such as, in 2020, the Chinese government spent US$ 296.42 Mn. in Shouhang IHW Resources Saving Technology Co., Ltd to set up 3 hydrogen plants and nearly 10 hydrogen positions for vehicles in the Datong, China.Direct Methanol Fuel Cells Market Segment Analysis
By application, the portable segment expected to grow at the highest 15% CAGR during the forecast period thanks to the increase in the consumer base of portable electronic devices and the growing demand for longer-lasting power provisions. The MMR report will also provide an accurate analysis of the contribution of the various segments to the growth of the market.Direct Methanol Fuel Cells Market Regional Anlaysis
The report offers a brief analysis of the major regions in the market, namely, Europe, Asia-Pacific, North America, Middle East & Africa and Latin America. APAC Direct Methanol Fuel cells Market was valued US$ xxMn. in 2020 and is expected to reach a value of US$ xx Mn. by 2029, with a CAGR of 66% during the forecast period. This is attributed to the rapid upsurge in DMFC application such as electronics automotive, and other industrial usage. This emerging regional market witness promising growth estimates and provides abundant opportunities for the industry contributors. The direct methanol fuel cells market, now, is at a promising stage and is characterized by a handful of enterprises. Initial high R&D costs are likely to ward off novel entrants from entering the fuel cell industry. The research study includes the profiles of leading companies operating in the global direct methanol fuel cells market. SFC Energy AG is a leading provider of hydrogen fuel cells and direct methanol for mobile and stationary hybrid power solutions. Company has award-winning serves and products a range of applications in defense & security, oil & gas, clean energy & mobility, and industry markets. The objective of the report is to present a comprehensive analysis of the Global Direct Methanol Fuel cells Market including all the stakeholders of the industry. The past and current status of the industry with forecasted market size and trends are presented in the report with the analysis of complicated data in simple language. The report covers all the aspects of the industry with a dedicated study of key players that includes market leaders, followers and new entrants. PORTER, SVOR, PESTEL analysis with the potential impact of micro-economic factors of the market has been presented in the report. External as well as internal factors that are supposed to affect the business positively or negatively have been analyzed, which will give a clear futuristic view of the industry to the decision-makers. The report also helps in understanding Global Direct Methanol Fuel Cells Market dynamics, structure by analyzing the market segments and projects the Global Direct Methanol Fuel cells Market size. Clear representation of competitive analysis of key players by Application, price, financial position, Product portfolio, growth strategies, and regional presence in the Global Direct Methanol Fuel cells Market make the report investor’s guide.Direct Methanol Fuel Cells Market Scope Inquiry Before Buying
Direct Methanol Fuel Cells Market Report Coverage Details Base Year: 2022 Forecast Period: 2023-2029 Historical Data: 2017 to 2022 Market Size in 2022: US $ 240.58 Bn. Forecast Period 2023 to 2029 CAGR: 12.9% Market Size in 2029: US $ 562.51 Bn. Segments Covered: by Component • Electrode • Membrane • Balance of System • Balance of Stack by Type • Serpentine Flow Field Design • Parallel Flow Field Design by Application • Portable • Stationary • Transportation Direct Methanol Fuel Cells Market, by Region
• North America (United States, Canada and Mexico) • Europe (UK, France, Germany, Italy, Spain, Sweden, Austria and Rest of Europe) • Asia Pacific (China, South Korea, Japan, India, Australia, Indonesia, Malaysia, Vietnam, Taiwan, Bangladesh, Pakistan and Rest of APAC) • Middle East and Africa (South Africa, GCC, Egypt, Nigeria and Rest of ME&A) • South America (Brazil, Argentina Rest of South America)Direct Methanol Fuel Cells Market Key Players
• SFC Energy AG • Samsung SDI • Ballard Power Systems Inc. • Oorja Protonics Inc. • Horizon Fuel Cell Technologies • Meoh Power, Inc. • Bren-Tronics Incorporated • Treadstone Technologies Inc. • Viaspace Inc. • E. I. Du Pont De Nemours and Company • Ird Fuel Cell A/S • Johnson Matthey • Fujikura Limited • Antig Technology Co. Ltd. • DuPont Fuel Cell • Polyfuel Inc • Blue World Technologies • Fischer bunch GmbH • Roland Gumpert • SerEnergy A/S • AIWAYS • GenCell Energy Frequently Asked Questions: 1. Which region has the largest share in Global Direct Methanol Fuel Cells Market? Ans: Asia Pacific region held the highest share in 2022. 2. What is the growth rate of Global Direct Methanol Fuel Cells Market? Ans: The Global Direct Methanol Fuel Cells Market is growing at a CAGR of 12.9% during forecasting period 2023-2029. 3. What is scope of the Global Direct Methanol Fuel Cells Market report? Ans: Global Direct Methanol Fuel Cells Market report helps with the PESTEL, PORTER, COVID-19 Impact analysis, Recommendations for Investors & Leaders, and market estimation of the forecast period. 4. Who are the key players in Global Direct Methanol Fuel Cells Market? Ans: The important key players in the Global Direct Methanol Fuel Cells Market are – SFC Energy AG, Samsung SDI, Ballard Power Systems Inc., Oorja Protonics Inc., Horizon Fuel Cell Technologies, Meoh Power, Inc., Bren-Tronics Incorporated, Treadstone Technologies Inc., Viaspace Inc., E. I. Du Pont De Nemours and Company, Ird Fuel Cell A/S, Johnson Matthey, Fujikura Limited, Antig Technology Co. Ltd., DuPont Fuel Cell, Polyfuel Inc, Blue World Technologies, Fischer bunch GmbH, Roland Gumpert, SerEnergy A/S, AIWAYS, GenCell Energy 5. What is the study period of this Market? Ans: The Global Direct Methanol Fuel Cells Market is studied from 2022 to 2029.
Global Direct Methanol Fuel Cells Market 1. Preface 1.1. Report Scope and Market Segmentation 1.2. Research Highlights 1.3. Research Objectives 2. Assumptions and Research Methodology 2.1. Report Assumptions 2.2. Abbreviations 2.3. Research Methodology 2.3.1. Secondary Research 2.3.1.1. Secondary data 2.3.1.2. Secondary Sources 2.3.2. Primary Research 2.3.2.1. Data from Primary Sources 2.3.2.2. Breakdown of Primary Sources 3. Executive Summary: Global Direct Methanol Fuel cells Market Size, by Market Value (US$ Bn) 4. Market Overview 4.1. Introduction 4.2. Market Indicator 4.2.1. Drivers 4.2.2. Restraints 4.2.3. Opportunities 4.2.4. Challenges 4.3. Porter’s Analysis 4.4. Value Chain Analysis 4.5. Market Risk Analysis 4.6. SWOT Analysis 4.7. Industry Trends and Emerging Technologies 5. Supply Side and Demand Side Indicators 6. Global Direct Methanol Fuel cells Market Analysis and Forecast 6.1. Direct Methanol Fuel cells Market Size & Y-o-Y Growth Analysis 6.1.1. North America 6.1.2. Europe 6.1.3. Asia Pacific 6.1.4. Middle East & Africa 6.1.5. South America 7. Global Direct Methanol Fuel cells Market Analysis and Forecast, By Application 7.1. Introduction and Definition 7.2. Key Findings 7.3. Direct Methanol Fuel cells Market Value Share Analysis, By Application 7.4. Direct Methanol Fuel cells Market Size (US$ Bn) Forecast, By Application 7.5. Direct Methanol Fuel cells Market Analysis, By Application 7.6. Direct Methanol Fuel cells Market Attractiveness Analysis, By Application 8. Global Direct Methanol Fuel cells Market Analysis and Forecast, By Type 8.1. Introduction and Definition 8.2. Key Findings 8.3. Direct Methanol Fuel cells Market Value Share Analysis, By Type 8.4. Direct Methanol Fuel cells Market Size (US$ Bn) Forecast, By Type 8.5. Direct Methanol Fuel cells Market Analysis, By Type 8.6. Direct Methanol Fuel cells Market Attractiveness Analysis, By Type 9. Global Direct Methanol Fuel cells Market Analysis and Forecast, By Component 9.1. Introduction and Definition 9.2. Key Findings 9.3. Direct Methanol Fuel cells Market Value Share Analysis, By Component 9.4. Direct Methanol Fuel cells Market Size (US$ Bn) Forecast, By Component 9.5. Direct Methanol Fuel cells Market Analysis, By Component 9.6. Direct Methanol Fuel cells Market Attractiveness Analysis, By Component 10. Global Direct Methanol Fuel cells Market Analysis, by Region 10.1. Direct Methanol Fuel cells Market Value Share Analysis, by Region 10.2. Direct Methanol Fuel cells Market Size (US$ Bn) Forecast, by Region 10.3. Direct Methanol Fuel cells Market Attractiveness Analysis, by Region 11. North America Direct Methanol Fuel cells Market Analysis 11.1. Key Findings 11.2. North America Direct Methanol Fuel cells Market Overview 11.3. North America Direct Methanol Fuel cells Market Value Share Analysis, By Application 11.4. North America Direct Methanol Fuel cells Market Forecast, By Application 11.4.1. Portable 11.4.2. Stationary 11.4.3. Transportation 11.5. North America Direct Methanol Fuel cells Market Value Share Analysis, By Type 11.6. North America Direct Methanol Fuel cells Market Forecast, By Type 11.6.1. Serpentine Flow Field Design 11.6.2. Parallel Flow Field Design 11.7. North America Direct Methanol Fuel cells Market Value Share Analysis, By Component 11.8. North America Direct Methanol Fuel cells Market Forecast, By Component 11.8.1. Electrode 11.8.2. Membrane 11.8.3. Balance of System 11.8.4. Balance of Stack 11.9. North America Direct Methanol Fuel cells Market Value Share Analysis, by Country 11.10. North America Direct Methanol Fuel cells Market Forecast, by Country 11.10.1. U.S. 11.10.2. Canada 11.11. North America Direct Methanol Fuel cells Market Analysis, by Country 11.12. U.S. Direct Methanol Fuel cells Market Forecast, By Application 11.12.1. Portable 11.12.2. Stationary 11.12.3. Transportation 11.13. U.S. Direct Methanol Fuel cells Market Forecast, By Type 11.13.1. Serpentine Flow Field Design 11.13.2. Parallel Flow Field Design 11.14. U.S. Direct Methanol Fuel cells Market Forecast, By Component 11.14.1. Electrode 11.14.2. Membrane 11.14.3. Balance of System 11.14.4. Balance of Stack 11.15. Canada Direct Methanol Fuel cells Market Forecast, By Application 11.15.1. Portable 11.15.2. Stationary 11.15.3. Transportation 11.16. Canada Direct Methanol Fuel cells Market Forecast, By Type 11.16.1. Serpentine Flow Field Design 11.16.2. Parallel Flow Field Design 11.17. Canada Direct Methanol Fuel cells Market Forecast, By Component 11.17.1. Electrode 11.17.2. Membrane 11.17.3. Balance of System 11.17.4. Balance of Stack 11.18. North America Direct Methanol Fuel cells Market Attractiveness Analysis 11.18.1. By Application 11.18.2. By Type 11.18.3. By Component 11.19. PEST Analysis 11.20. Key Trends 11.21. Key Developments 12. Europe Direct Methanol Fuel cells Market Analysis 12.1. Key Findings 12.2. Europe Direct Methanol Fuel cells Market Overview 12.3. Europe Direct Methanol Fuel cells Market Value Share Analysis, By Application 12.4. Europe Direct Methanol Fuel cells Market Forecast, By Application 12.4.1. Portable 12.4.2. Stationary 12.4.3. Transportation 12.5. Europe Direct Methanol Fuel cells Market Value Share Analysis, By Type 12.6. Europe Direct Methanol Fuel cells Market Forecast, By Type 12.6.1. Serpentine Flow Field Design 12.6.2. Parallel Flow Field Design 12.7. Europe Direct Methanol Fuel cells Market Value Share Analysis, By Component 12.8. Europe Direct Methanol Fuel cells Market Forecast, By Component 12.8.1. Electrode 12.8.2. Membrane 12.8.3. Balance of System 12.8.4. Balance of Stack 12.9. Europe Direct Methanol Fuel cells Market Value Share Analysis, by Country 12.10. Europe Direct Methanol Fuel cells Market Forecast, by Country 12.10.1. Germany 12.10.2. UK 12.10.3. France 12.10.4. Italy 12.10.5. Spain 12.10.6. Norway 12.10.7. Russia 12.11. Europe Direct Methanol Fuel cells Market Analysis, by Country 12.12. Germany Direct Methanol Fuel cells Market Forecast, By Application 12.12.1. Portable 12.12.2. Stationary 12.12.3. Transportation 12.13. Germany Direct Methanol Fuel cells Market Forecast, By Type 12.13.1. Serpentine Flow Field Design 12.13.2. Parallel Flow Field Design 12.14. Germany Direct Methanol Fuel cells Market Forecast, By Component 12.14.1. Electrode 12.14.2. Membrane 12.14.3. Balance of System 12.14.4. Balance of Stack 12.15. U.K. Direct Methanol Fuel cells Market Forecast, By Application 12.15.1. Portable 12.15.2. Stationary 12.15.3. Transportation 12.16. U.K. Direct Methanol Fuel cells Market Forecast, By Type 12.16.1. Serpentine Flow Field Design 12.16.2. Parallel Flow Field Design 12.17. U.K. Direct Methanol Fuel cells Market Forecast, By Component 12.17.1. Electrode 12.17.2. Membrane 12.17.3. Balance of System 12.17.4. Balance of Stack 12.18. France Direct Methanol Fuel cells Market Forecast, By Application 12.18.1. Portable 12.18.2. Stationary 12.18.3. Transportation 12.19. France Direct Methanol Fuel cells Market Forecast, By Type 12.19.1. Serpentine Flow Field Design 12.19.2. Parallel Flow Field Design 12.20. France Direct Methanol Fuel cells Market Forecast, By Component 12.20.1. Electrode 12.20.2. Membrane 12.20.3. Balance of System 12.20.4. Balance of Stack 12.21. Italy Direct Methanol Fuel cells Market Forecast, By Application 12.21.1. Portable 12.21.2. Stationary 12.21.3. Transportation 12.22. Italy Direct Methanol Fuel cells Market Forecast, By Type 12.22.1. Serpentine Flow Field Design 12.22.2. Parallel Flow Field Design 12.23. Italy Direct Methanol Fuel cells Market Forecast, By Component 12.23.1. Electrode 12.23.2. Membrane 12.23.3. Balance of System 12.23.4. Balance of Stack 12.24. Spain Direct Methanol Fuel cells Market Forecast, By Application 12.24.1. Portable 12.24.2. Stationary 12.24.3. Transportation 12.25. Spain Direct Methanol Fuel cells Market Forecast, By Type 12.25.1. Serpentine Flow Field Design 12.25.2. Parallel Flow Field Design 12.26. Spain Direct Methanol Fuel cells Market Forecast, By Component 12.26.1. Electrode 12.26.2. Membrane 12.26.3. Balance of System 12.26.4. Balance of Stack 12.27. Norway Direct Methanol Fuel cells Market Forecast, By Application 12.27.1. Portable 12.27.2. Stationary 12.27.3. Transportation 12.28. Norway Direct Methanol Fuel cells Market Forecast, By Type 12.28.1. Serpentine Flow Field Design 12.28.2. Parallel Flow Field Design 12.29. Norway Direct Methanol Fuel cells Market Forecast, By Component 12.29.1. Electrode 12.29.2. Membrane 12.29.3. Balance of System 12.29.4. Balance of Stack 12.30. Russia Direct Methanol Fuel cells Market Forecast, By Application 12.30.1. Portable 12.30.2. Stationary 12.30.3. Transportation 12.31. Russia Direct Methanol Fuel cells Market Forecast, By Type 12.31.1. Serpentine Flow Field Design 12.31.2. Parallel Flow Field Design 12.32. Russia Direct Methanol Fuel cells Market Forecast, By Component 12.32.1. Electrode 12.32.2. Membrane 12.32.3. Balance of System 12.32.4. Balance of Stack 12.33. Europe Direct Methanol Fuel cells Market Attractiveness Analysis 12.33.1. By Application 12.33.2. By Type 12.33.3. By Component 12.34. PEST Analysis 12.35. Key Trends 12.36. Key Developments 13. Asia Pacific Direct Methanol Fuel cells Market Analysis 13.1. Key Findings 13.2. Asia Pacific Direct Methanol Fuel cells Market Overview 13.3. Asia Pacific Direct Methanol Fuel cells Market Value Share Analysis, By Application 13.4. Asia Pacific Direct Methanol Fuel cells Market Forecast, By Application 13.4.1. Portable 13.4.2. Stationary 13.4.3. Transportation 13.5. Asia Pacific Direct Methanol Fuel cells Market Value Share Analysis, By Type 13.6. Asia Pacific Direct Methanol Fuel cells Market Forecast, By Type 13.6.1. Serpentine Flow Field Design 13.6.2. Parallel Flow Field Design 13.7. Asia Pacific Direct Methanol Fuel cells Market Value Share Analysis, By Component 13.8. Asia Pacific Direct Methanol Fuel cells Market Forecast, By Component 13.8.1. Electrode 13.8.2. Membrane 13.8.3. Balance of System 13.8.4. Balance of Stack 13.9. Asia Pacific Direct Methanol Fuel cells Market Value Share Analysis, by Country 13.10. Asia Pacific Direct Methanol Fuel cells Market Forecast, by Country 13.10.1. China 13.10.2. India 13.10.3. Japan 13.10.4. South Korea 13.10.5. Australia 13.10.6. Malaysia 13.10.7. Indonesia 13.10.8. Vietnam 13.11. Asia Pacific Direct Methanol Fuel cells Market Analysis, by Country 13.12. China Direct Methanol Fuel cells Market Forecast, By Application 13.12.1. Portable 13.12.2. Stationary 13.12.3. Transportation 13.13. China Direct Methanol Fuel cells Market Forecast, By Type 13.13.1. Serpentine Flow Field Design 13.13.2. Parallel Flow Field Design 13.14. China Direct Methanol Fuel cells Market Forecast, By Component 13.14.1. Electrode 13.14.2. Membrane 13.14.3. Balance of System 13.14.4. Balance of Stack 13.15. India Direct Methanol Fuel cells Market Forecast, By Application 13.15.1. Portable 13.15.2. Stationary 13.15.3. Transportation 13.16. India Direct Methanol Fuel cells Market Forecast, By Type 13.16.1. Serpentine Flow Field Design 13.16.2. Parallel Flow Field Design 13.17. India Direct Methanol Fuel cells Market Forecast, By Component 13.17.1. Electrode 13.17.2. Membrane 13.17.3. Balance of System 13.17.4. Balance of Stack 13.18. Japan Direct Methanol Fuel cells Market Forecast, By Application 13.18.1. Portable 13.18.2. Stationary 13.18.3. Transportation 13.19. Japan Direct Methanol Fuel cells Market Forecast, By Type 13.19.1. Serpentine Flow Field Design 13.19.2. Parallel Flow Field Design 13.20. Japan Direct Methanol Fuel cells Market Forecast, By Component 13.20.1. Electrode 13.20.2. Membrane 13.20.3. Balance of System 13.20.4. Balance of Stack 13.21. South Korea Direct Methanol Fuel cells Market Forecast, By Application 13.21.1. Portable 13.21.2. Stationary 13.21.3. Transportation 13.22. South Korea Direct Methanol Fuel cells Market Forecast, By Type 13.22.1. Serpentine Flow Field Design 13.22.2. Parallel Flow Field Design 13.23. South Korea Direct Methanol Fuel cells Market Forecast, By Component 13.23.1. Electrode 13.23.2. Membrane 13.23.3. Balance of System 13.23.4. Balance of Stack 13.24. Australia Direct Methanol Fuel cells Market Forecast, By Application 13.24.1. Portable 13.24.2. Stationary 13.24.3. Transportation 13.25. Australia Direct Methanol Fuel cells Market Forecast, By Type 13.25.1. Serpentine Flow Field Design 13.25.2. Parallel Flow Field Design 13.26. Australia Direct Methanol Fuel cells Market Forecast, By Component 13.26.1. Electrode 13.26.2. Membrane 13.26.3. Balance of System 13.26.4. Balance of Stack 13.27. Malaysia Direct Methanol Fuel cells Market Forecast, By Application 13.27.1. Portable 13.27.2. Stationary 13.27.3. Transportation 13.28. Malaysia Direct Methanol Fuel cells Market Forecast, By Type 13.28.1. Serpentine Flow Field Design 13.28.2. Parallel Flow Field Design 13.29. Malaysia Direct Methanol Fuel cells Market Forecast, By Component 13.29.1. Electrode 13.29.2. Membrane 13.29.3. Balance of System 13.29.4. Balance of Stack 13.30. Indonesia Direct Methanol Fuel cells Market Forecast, By Application 13.30.1. Portable 13.30.2. Stationary 13.30.3. Transportation 13.31. Indonesia Direct Methanol Fuel cells Market Forecast, By Type 13.31.1. Serpentine Flow Field Design 13.31.2. Parallel Flow Field Design 13.32. Indonesia Direct Methanol Fuel cells Market Forecast, By Component 13.32.1. Electrode 13.32.2. Membrane 13.32.3. Balance of System 13.32.4. Balance of Stack 13.33. Vietnam Direct Methanol Fuel cells Market Forecast, By Application 13.33.1. Portable 13.33.2. Stationary 13.33.3. Transportation 13.34. Vietnam Direct Methanol Fuel cells Market Forecast, By Type 13.34.1. Serpentine Flow Field Design 13.34.2. Parallel Flow Field Design 13.35. Vietnam Direct Methanol Fuel cells Market Forecast, By Component 13.35.1. Electrode 13.35.2. Membrane 13.35.3. Balance of System 13.35.4. Balance of Stack 13.36. Asia Pacific Direct Methanol Fuel cells Market Attractiveness Analysis 13.36.1. By Application 13.36.2. By Type 13.36.3. By Component 13.37. PEST Analysis 13.38. Key Trends 13.39. Key Developments 14. Middle East & Africa Direct Methanol Fuel cells Market Analysis 14.1. Key Findings 14.2. Middle East & Africa Direct Methanol Fuel cells Market Overview 14.3. Middle East & Africa Direct Methanol Fuel cells Market Value Share Analysis, By Application 14.4. Middle East & Africa Direct Methanol Fuel cells Market Forecast, By Application 14.4.1. Portable 14.4.2. Stationary 14.4.3. Transportation 14.5. Middle East & Africa Direct Methanol Fuel cells Market Value Share Analysis, By Type 14.6. Middle East & Africa Direct Methanol Fuel cells Market Forecast, By Type 14.6.1. Serpentine Flow Field Design 14.6.2. Parallel Flow Field Design 14.7. Middle East & Africa Direct Methanol Fuel cells Market Value Share Analysis, By Component 14.8. Middle East & Africa Direct Methanol Fuel cells Market Forecast, By Component 14.8.1. Electrode 14.8.2. Membrane 14.8.3. Balance of System 14.8.4. Balance of Stack 14.9. Middle East & Africa Direct Methanol Fuel cells Market Value Share Analysis, by Country 14.10. Middle East & Africa Direct Methanol Fuel cells Market Forecast, by Country 14.10.1. GCC Countries 14.10.2. South Africa 14.10.3. Nigeria 14.10.4. Egypt 14.11. Middle East & Africa Direct Methanol Fuel cells Market Analysis, by Country 14.12. GCC Direct Methanol Fuel cells Market Forecast, By Application 14.12.1. Portable 14.12.2. Stationary 14.12.3. Transportation 14.13. GCC Direct Methanol Fuel cells Market Forecast, By Type 14.13.1. Serpentine Flow Field Design 14.13.2. Parallel Flow Field Design 14.14. GCC Direct Methanol Fuel cells Market Forecast, By Component 14.14.1. Electrode 14.14.2. Membrane 14.14.3. Balance of System 14.14.4. Balance of Stack 14.15. South Africa Direct Methanol Fuel cells Market Forecast, By Application 14.15.1. Portable 14.15.2. Stationary 14.15.3. Transportation 14.16. South Africa Direct Methanol Fuel cells Market Forecast, By Type 14.16.1. Serpentine Flow Field Design 14.16.2. Parallel Flow Field Design 14.17. South Africa Direct Methanol Fuel cells Market Forecast, By Component 14.17.1. Electrode 14.17.2. Membrane 14.17.3. Balance of System 14.17.4. Balance of Stack 14.18. Nigeria Direct Methanol Fuel cells Market Forecast, By Application 14.18.1. Portable 14.18.2. Stationary 14.18.3. Transportation 14.19. Nigeria Direct Methanol Fuel cells Market Forecast, By Type 14.19.1. Serpentine Flow Field Design 14.19.2. Parallel Flow Field Design 14.20. Nigeria Direct Methanol Fuel cells Market Forecast, By Component 14.20.1. Electrode 14.20.2. Membrane 14.20.3. Balance of System 14.20.4. Balance of Stack 14.21. Egypt Direct Methanol Fuel cells Market Forecast, By Application 14.21.1. Portable 14.21.2. Stationary 14.21.3. Transportation 14.22. Egypt Direct Methanol Fuel cells Market Forecast, By Type 14.22.1. Serpentine Flow Field Design 14.22.2. Parallel Flow Field Design 14.23. Egypt Direct Methanol Fuel cells Market Forecast, By Component 14.23.1. Electrode 14.23.2. Membrane 14.23.3. Balance of System 14.23.4. Balance of Stack 14.24. Middle East & Africa Direct Methanol Fuel cells Market Attractiveness Analysis 14.24.1. By Application 14.24.2. By Type 14.24.3. By Component 14.25. PEST Analysis 14.26. Key Trends 14.27. Key Developments 15. South America Direct Methanol Fuel cells Market Analysis 15.1. Key Findings 15.2. South America Direct Methanol Fuel cells Market Overview 15.3. South America Direct Methanol Fuel cells Market Value Share Analysis, By Application 15.4. South America Direct Methanol Fuel cells Market Forecast, By Application 15.4.1. Portable 15.4.2. Stationary 15.4.3. Transportation 15.5. South America Direct Methanol Fuel cells Market Value Share Analysis, By Type 15.6. South America Direct Methanol Fuel cells Market Forecast, By Type 15.6.1. Serpentine Flow Field Design 15.6.2. Parallel Flow Field Design 15.7. South America Direct Methanol Fuel cells Market Value Share Analysis, By Component 15.8. South America Direct Methanol Fuel cells Market Forecast, By Component 15.8.1. Electrode 15.8.2. Membrane 15.8.3. Balance of System 15.8.4. Balance of Stack 15.9. South America Direct Methanol Fuel cells Market Value Share Analysis, by Country 15.10. South America Direct Methanol Fuel cells Market Forecast, by Country 15.10.1. Mexico 15.10.2. Brazil 15.10.3. Argentina 15.11. South America Direct Methanol Fuel cells Market Analysis, by Country 15.12. Brazil Direct Methanol Fuel cells Market Forecast, By Application 15.12.1. Portable 15.12.2. Stationary 15.12.3. Transportation 15.13. Brazil Direct Methanol Fuel cells Market Forecast, By Type 15.13.1. Serpentine Flow Field Design 15.13.2. Parallel Flow Field Design 15.14. Brazil Direct Methanol Fuel cells Market Forecast, By Component 15.14.1. Electrode 15.14.2. Membrane 15.14.3. Balance of System 15.14.4. Balance of Stack 15.15. Mexico Direct Methanol Fuel cells Market Forecast, By Application 15.15.1. Portable 15.15.2. Stationary 15.15.3. Transportation 15.16. Mexico Direct Methanol Fuel cells Market Forecast, By Type 15.16.1. Serpentine Flow Field Design 15.16.2. Parallel Flow Field Design 15.17. Mexico Direct Methanol Fuel cells Market Forecast, By Component 15.17.1. Electrode 15.17.2. Membrane 15.17.3. Balance of System 15.17.4. Balance of Stack 15.18. Argentina Direct Methanol Fuel cells Market Forecast, By Application 15.18.1. Portable 15.18.2. Stationary 15.18.3. Transportation 15.19. Argentina Direct Methanol Fuel cells Market Forecast, By Type 15.19.1. Serpentine Flow Field Design 15.19.2. Parallel Flow Field Design 15.20. Argentina Direct Methanol Fuel cells Market Forecast, By Component 15.20.1. Electrode 15.20.2. Membrane 15.20.3. Balance of System 15.20.4. Balance of Stack 15.21. South America Direct Methanol Fuel cells Market Attractiveness Analysis 15.21.1. By Application 15.21.2. By Type 15.21.3. By Component 15.22. PEST Analysis 15.23. Key Trends 15.24. Key Developments 16. Company Profiles 16.1. Market Share Analysis, by Company 16.2. Competition Matrix 16.2.1. Competitive Benchmarking of key players by price, presence, market share, Applications and R&D investment 16.2.2. New Product Launches and Product Enhancements 16.2.3. Market Consolidation 16.2.3.1. M&A by Regions, Investment and Applications 16.2.3.2. M&A Key Players, Forward Integration and Backward Integration 16.3. Company Profiles: Key Players 16.3.1. SFC Energy AG 16.3.1.1. Company Overview 16.3.1.2. Financial Overview 16.3.1.3. Product Portfolio 16.3.1.4. Business Strategy 16.3.1.5. Recent Developments 16.3.1.6. Development Footprint 16.3.2. Samsung SDI 16.3.3. Ballard Power Systems Inc. 16.3.4. Oorja Protonics Inc. 16.3.5. Horizon Fuel Cell Technologies 16.3.6. Meoh Power, Inc. 16.3.7. Bren-Tronics Incorporated 16.3.8. Treadstone Technologies Inc. 16.3.9. Viaspace Inc. 16.3.10. E. I. Du Pont De Nemours and Company 16.3.11. Ird Fuel Cell A/S 16.3.12. Johnson Matthey 16.3.13. Fujikura Limited 16.3.14. Antig Technology Co. Ltd. 16.3.15. DuPont Fuel Cell 16.3.16. Polyfuel Inc 16.3.17. Blue World Technologies 16.3.18. Fischer bunch GmbH 16.3.19. Roland Gumpert 16.3.20. SerEnergy A/S 16.3.21. AIWAYS 16.3.22. GenCell Energy 17. Primary Key Insights