Global Hydrogen Energy Transition Market size was valued at USD 159.53 Bn. in 2023 and the total Hydrogen Energy Transition revenue is expected to grow by 9.8 % from 2024 to 2030, reaching nearly USD 306.96 Bn.Hydrogen Energy Transition Market Overview:
The hydrogen energy transition refers to the shift from fossil fuel-based energy systems to those powered by hydrogen as a clean and sustainable energy source.It gains global recognition as a pivotal solution for reducing carbon emissions and transitioning from fossil fuels to cleaner energy sources therefore the hydrogen energy transition market is experiencing rapid growth. Hydrogen, obtained through natural gas, or water electrolysis, renewable energy, is emerging as a versatile and sustainable fuel. This growth is primarily fueled byfavorable policies, government support, and increased private-sector investments. Governments worldwide are offering financial incentives and establishing regulatory frameworks to promote the development of hydrogen infrastructure and related technologies. Various industries,power generation including the transportation industry, and heating, are adopting hydrogen as a clean energy alternative. Green hydrogen, produced from renewable energy sources, is gaining traction as the preferred production method in the Hydrogen Energy Transition Market. The market for hydrogen energy transition is expanding dramatically as a result of governments, corporations, and investors realizing its potential. Governments all over the world are making large expenditures and establishing challenging goals to promote the development of hydrogen technology and infrastructure. For instance, the European Union intends to invest €470 billion (about $550 billion) by 2050 in initiatives involving hydrogen. The electrolyzer market, by 2030, it is expected that a crucial element in the electrolysis-based hydrogen production process will have a combined capacity of more than 100 GW. Electrolyzer costs have decreased by more than 40%, which has helped to lower the cost of manufacturing hydrogen Since 2014. The adoption of green hydrogen is being fueled by this cost reduction as well as the expanding capacity of renewable hydrogen production. As hydrogen fuel cells and hydrogen-powered vehicles gain popularity the demand for hydrogen is significantly influenced by the transportation industry. With boosting the use of fuel cell vehicles, more than 5,500 hydrogen refueling stations are predicted to exist worldwide by 2030. Thehydrogen energy transition market offers significant opportunities for innovation, cost reduction, and stakeholder collaboration to overcome obstacles and quicken the shift to a clean and sustainable energy future, despite obstacles like high production costs and limited infrastructure.To know about the Research Methodology :- Request Free Sample Report
Hydrogen Energy Transition Market Dynamics
Hydrogen Energy Transition Market Drivers Private Sector Investments Propel the Growth of the Hydrogen Energy Transition Market The hydrogen energy transition market is expanding and growing as a result of investments made by the private sector. The enormous potential of hydrogen is realized by Businesses from a variety of sectors the as a clean and sustainable energy source, which is prompting large investments in hydrogen technology development, implementation, and research. To support their decarbonization goals, traditional energy companies are diversifying their holdings and investing in hydrogen projects. These businesses are actively promoting the implementation of hydrogen production, storage, and distribution networks by utilizing their experience in energy infrastructure and financing. The development of hydrogen fuel cells and hydrogen-powered cars is also receiving significant funding from the automobile industry and transportation businesses. They are aware of the benefits of hydrogen, such as its quick refueling, longer driving ranges, and absence of tailpipe emissions. The investments aim to advance the commercialization and scalability of hydrogen-powered transportation solutions, encompassing passenger vehicles, buses, trucks, and even trains and ships. Furthermore, financial institutions and venture capital firms are directing significant funds toward hydrogen-related startups and projects. They recognize the long-term growth potential and economic opportunities associated with the Hydrogen Energy Transition Market.Investments are flowing into crucial areas such as electrolyzer manufacturing, hydrogen infrastructure development, hydrogen fueling stations, and hydrogen-based power generation projects. The involvement of multinational corporations is also shaping the hydrogen market. Collaborations between technology companies and hydrogen industry players are further driving innovation and cost reduction. Partnerships between established technology giants and emerging hydrogen startups are combining expertise in artificial intelligence, automation, and advanced materials to develop cutting-edge hydrogen solutions. These collaborations accelerate the development of more efficient and affordable hydrogen technologies. The increasing private sector investments not only bring financial resources but also foster market stability and confidence. They create a favorable business environment, attracting additional investments and stimulating a positive cycle of growth and innovation. Hydrogen Energy Transition Market Restraints Lack of Adequate Infrastructure Poses Challenges to the Hydrogen Energy Transition Market Insufficient infrastructure presents a significant challenge to the growth of the hydrogen energy transition market. While the potential of hydrogen as a clean and sustainable energy source is widely recognized, the limited availability of infrastructure for production, storage, distribution, and refueling hinders the widespread adoption of hydrogen technologies. One major challenge lies in the insufficient hydrogen production capacity. The current capacity falls short of meeting the increasing demand, particularly in sectors like transportation and industrial applications. Expanding production infrastructure necessitates substantial investments in electrolyzers, production facilities, and supply chains. Storage and transportation of hydrogen also pose challenges. Hydrogen's low energy density requires specialized storage solutions. Existing methods such as compressed gas or cryogenic liquid storage have limitations in terms of volume, safety, and cost-effectiveness. Developing and implementing advanced storage technologies like solid-state hydrogen storage or chemical carriers is crucial to overcome these challenges. Furthermore, the distribution infrastructure for hydrogen is limited, especially when compared to conventional fueling networks. Establishing a comprehensive hydrogen distribution network, including pipelines, transport vessels, and refueling stations, requires significant investments and collaborative efforts among stakeholders. Hydrogen Energy Transition Market Opportunity Technological Advancements boost the Growth of the Hydrogen Energy Transition Market Technological developments that have increased the effectiveness and viability of hydrogen as an energy source is growing the hydrogen energy transition market. Ongoing research and development are all advancing due to the transportation, storage, production, and use of hydrogen. Furthermore, to assuring a consistent and dependable hydrogen supply, developments in hydrogen storage technology are essential. Through material innovations including solid-state hydrogen storage and high-pressure tanks Higher storage capacity and better hydrogen distribution are made possible. The performance and range of hydrogen-powered vehicles have improved as a result of developments in hydrogen fuel cell technology in the transportation industry. Infrastructure improvements for hydrogen refueling are addressing the drawbacks of inadequate infrastructure and boosting the wider adoption of hydrogen fuel cell vehicles. These improvements include high-capacity and quick-fill stations.The incorporation of hydrogen with renewable energy sources like wind and solar power is a significant technological achievement. Green hydrogen, which is carbon-neutral and has a smaller environmental impact than hydrogen sourced from fossil fuels, can be produced through electrolysis using renewable energy. Moreover, advancements in hydrogen utilization technologies are expanding the applications of hydrogen across various industries. For example, hydrogen can be used in fuel cells for efficient electricity generation and clean. Hydrogen can replace fossil fuels as a reducing agent in sectors like the steel industry, drastically lowering carbon emissions. The development and widespread use of hydrogen as a sustainable and clean energy source is being fueled by these technological advances.Hydrogen Energy Transition Market Segment Analysis:
Based on the Production Method, the Electrolysis segment of the Hydrogen Energy Transition Marketdominated the market in the year 2023 and is expected to continue its dominance during the forecast period. Involves splitting water molecules into hydrogen and oxygen using electricity. Renewable energy sources like solar or wind power are gaining a lot of attention since they can produce "green hydrogen" when powered. Electrolysis has seized the lead as a result of the increased focus on decarbonization and the need for clean, sustainable energy sources. Without releasing carbon dioxide electrolysis can make hydrogen, it is a process that is good for the environment. It supports the objective of shifting to a low-carbon economy and lessening dependency on fossil fuels.Additionally, electrolysis offers versatility in terms of scalability and deployment. From modest on-site installations to substantial industrial facilities It can be used on a range of scales. Thanks to its adaptability, electrolysis can be used in a variety of settings, including manufacturing,power generation, heating, and transportation. In addition, electrolysis technology is improving in terms of cost and efficiency, making it more competitive with other production techniques from an economic standpoint. Improvements in electrolyzer design, materials, and system integration have contributed to higher efficiency levels and lower capital and operational costs. These factors have further propelled the dominance of electrolysis in the hydrogen energy transition market. Based on the Application,the Fuel Cells segment dominated theHydrogen Energy Transition Market market in the year 2023 and is expected to continue its dominance during the forecast period. The fuel cells of hydrogen are increasingly being adopted to power a range of vehicles, and buses, including passenger cars, and heavy-duty trucks. Fuel cell vehicles’ advantages, such as longer driving ranges, shorter refueling times compared to electric vehicles, and zero tailpipe emissions, make them a promising solution for reducing carbon emissions and addressing air pollution in transportation. In stationary power generation systems, fuel cells also play a significant role. For the purpose of clean electricity, and supplying dependable, they are employed in commercial, residential, and industrial contexts. Over other forms of power generation due to their advantages, including their minimal emissions ,high efficacy, and silent operation, fuel cells can be used in both on- and off-grid applications. Furthermore, the decentralized structure of fuel cells enables their deployment at the point of use, minimizing the transmission and distribution losses linked to centralized power generation. Because of this quality, fuel cells are particularly appealing in rural or off-the-grid locations with sporadic or unstable grid connectivity. The market for hydrogen energy transition is dominated by fuel cells due to their growing use in stationary power generation and transportation. Fuel cells are expected to play a crucial role in reducing carbon emissions, improving air quality, and providing clean and efficient energy solutions in various sectors as technology continues to advance.
Hydrogen Energy Transition Market Regional Insights:
Europe region dominated the Hydrogen Energy Transition Market in the year 2023 and is expected to continue its dominance during the forecast period. The region's unwavering commitment to ambitious climate goals and carbon emissions reduction has propelled its dominance in this market. The European Union has placed hydrogen at the forefront of its strategy for a sustainable future, resulting in substantial investments in hydrogen technologies and infrastructuretargets of achieving climate neutrality by 2050. One of Europe's key advantages is its extensive network of renewable energy sources and its well-developed energy infrastructure. Europe has also implemented supportive policies and regulations that accelerate the adoption of hydrogen technologies. Governments across the region offer financial incentives, grants, and subsidies to foster research, development, and deployment of hydrogen infrastructure. Notably, the European Clean Hydrogen Alliance facilitates collaboration among industry stakeholders, governments, and research institutions, promoting the growth of a robust hydrogen ecosystem in Europe. The region's dominance is further strengthened by significant collaborations and partnerships among industry players, research institutions, and governments. These alliances span the entire hydrogen value chain, encompassing production, distribution, and utilization. By pooling its resources, expertise, and investments, Europe drives innovation and expedites the commercialization of hydrogen technologies.Hydrogen Energy Transition Market Scope: Inquire before buying
Hydrogen Energy Transition Market Report Coverage Details Base Year: 2023 Forecast Period: 2024-2030 Historical Data: 2018 to 2023 Market Size in 2023: US $ 159.53 Bn. Forecast Period 2024 to 2030 CAGR: 9.8% Market Size in 2030: US $ 306.96 Bn. Segments Covered: by Production Method Steam Methane Reforming Electrolysis Coal Gasification Biomass Gasification Others by End-Use Industry Transportation Power Generation Industry/Manufacturing Residential & Commercial Heating Others by Application Fuel Cells Heating Feedstock Power Generation Others Hydrogen Energy Transition 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)Hydrogen Energy Transition Market Key Players
1. Air Liquide SA 2. Linde plc 3. Air Products and Chemicals, Inc. 4. Plug Power Inc. 5. Ballard Power Systems Inc. 6. McPhy Energy S.A. 7. Nel ASA 8. ITM Power plc 9. Hydrogenics Corporation 10. Mitsubishi Power, Ltd. 11. Siemens Energy AG 12. Doosan Fuel Cell America, Inc. 13. Cummins Inc. 14. FuelCell Energy, Inc. 15. Toshiba Energy Systems & Solutions Corporation 16. Ceres Power Holdings plc 17. Bloom Energy Corporation 18. FuelCell Energy Solutions GmbH 19. SFC Energy AG 20. Horizon Fuel Cell Technologies Frequently Asked Questions: 1] What segments are covered in the Global Hydrogen Energy Transition Market report? Ans. The segments covered in the Hydrogen Energy Transition Market report are based on Production Method, Application, End-Use Industry, and Regions. 2] Which region is expected to hold the highest share in the Global Hydrogen Energy Transition Market? Ans. The Europe region is expected to hold the highest share of the Hydrogen Energy TransitionMarket. 3] What is the market size of the Global Hydrogen Energy Transition Market by 2030? Ans. The market size of the Hydrogen Energy Transition Market by 2030 is expected to reach US$ 306.96 Bn. 4] What is the forecast period for the Global Hydrogen Energy Transition Market? Ans. The forecast period for the Hydrogen Energy Transition Market is 2024-2030. 5] What was the market size of the Global Hydrogen Energy Transition Market in 2023? Ans. The market size of the Hydrogen Energy Transition Market in 2023 was valued at US$ 159.53 Bn.
1. Hydrogen Energy Transition Market Introduction 1.1. Study Assumption and Market Definition 1.2. Scope of the Study 1.3. Executive Summary 2. Hydrogen Energy Transition Market: Dynamics 2.1. Hydrogen Energy Transition Market Trends by Region 2.1.1. North America Hydrogen Energy Transition Market Trends 2.1.2. Europe Hydrogen Energy Transition Market Trends 2.1.3. Asia Pacific Hydrogen Energy Transition Market Trends 2.1.4. Middle East and Africa Hydrogen Energy Transition Market Trends 2.1.5. South America Hydrogen Energy Transition Market Trends 2.2. Hydrogen Energy Transition Market Dynamics by Region 2.2.1. North America 2.2.1.1. North America Hydrogen Energy Transition Market Drivers 2.2.1.2. North America Hydrogen Energy Transition Market Restraints 2.2.1.3. North America Hydrogen Energy Transition Market Opportunities 2.2.1.4. North America Hydrogen Energy Transition Market Challenges 2.2.2. Europe 2.2.2.1. Europe Hydrogen Energy Transition Market Drivers 2.2.2.2. Europe Hydrogen Energy Transition Market Restraints 2.2.2.3. Europe Hydrogen Energy Transition Market Opportunities 2.2.2.4. Europe Hydrogen Energy Transition Market Challenges 2.2.3. Asia Pacific 2.2.3.1. Asia Pacific Hydrogen Energy Transition Market Drivers 2.2.3.2. Asia Pacific Hydrogen Energy Transition Market Restraints 2.2.3.3. Asia Pacific Hydrogen Energy Transition Market Opportunities 2.2.3.4. Asia Pacific Hydrogen Energy Transition Market Challenges 2.2.4. Middle East and Africa 2.2.4.1. Middle East and Africa Hydrogen Energy Transition Market Drivers 2.2.4.2. Middle East and Africa Hydrogen Energy Transition Market Restraints 2.2.4.3. Middle East and Africa Hydrogen Energy Transition Market Opportunities 2.2.4.4. Middle East and Africa Hydrogen Energy Transition Market Challenges 2.2.5. South America 2.2.5.1. South America Hydrogen Energy Transition Market Drivers 2.2.5.2. South America Hydrogen Energy Transition Market Restraints 2.2.5.3. South America Hydrogen Energy Transition Market Opportunities 2.2.5.4. South America Hydrogen Energy Transition Market Challenges 2.3. PORTER’s Five Forces Analysis 2.4. PESTLE Analysis 2.5. Technology Roadmap 2.6. Regulatory Landscape by Region 2.6.1. North America 2.6.2. Europe 2.6.3. Asia Pacific 2.6.4. Middle East and Africa 2.6.5. South America 2.7. Key Opinion Leader Analysis For Hydrogen Energy Transition Industry 2.8. Analysis of Government Schemes and Initiatives For Hydrogen Energy Transition Industry 2.9. Hydrogen Energy Transition Market Trade Analysis 2.10. The Global Pandemic Impact on Hydrogen Energy Transition Market 3. Hydrogen Energy Transition Market: Global Market Size and Forecast by Segmentation by Demand and Supply Side (by Value in USD Million) 2023-2030 3.1. Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 3.1.1. Steam Methane Reforming 3.1.2. Electrolysis 3.1.3. Coal Gasification 3.1.4. Biomass Gasification 3.1.5. Others 3.2. Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 3.2.1. Transportation 3.2.2. Power Generation 3.2.3. Industry/Manufacturing 3.2.4. Residential & Commercial Heating 3.2.5. Others 3.3. Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 3.3.1. Fuel Cells 3.3.2. Heating 3.3.3. Feedstock 3.3.4. Power Generation 3.3.5. Others 3.4. Hydrogen Energy Transition Market Size and Forecast, by Region (2023-2030) 3.4.1. North America 3.4.2. Europe 3.4.3. Asia Pacific 3.4.4. Middle East and Africa 3.4.5. South America 4. North America Hydrogen Energy Transition Market Size and Forecast by Segmentation (by Value in USD Million) 2023-2030 4.1. North America Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 4.1.1. Steam Methane Reforming 4.1.2. Electrolysis 4.1.3. Coal Gasification 4.1.4. Biomass Gasification 4.1.5. Others 4.2. North America Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 4.2.1. Transportation 4.2.2. Power Generation 4.2.3. Industry/Manufacturing 4.2.4. Residential & Commercial Heating 4.2.5. Others 4.3. North America Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 4.3.1. Fuel Cells 4.3.2. Heating 4.3.3. Feedstock 4.3.4. Power Generation 4.3.5. Others 4.4. North America Hydrogen Energy Transition Market Size and Forecast, by Country (2023-2030) 4.4.1. United States 4.4.1.1. United States Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 4.4.1.1.1. Steam Methane Reforming 4.4.1.1.2. Electrolysis 4.4.1.1.3. Coal Gasification 4.4.1.1.4. Biomass Gasification 4.4.1.1.5. Others 4.4.1.2. United States Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 4.4.1.2.1. Transportation 4.4.1.2.2. Power Generation 4.4.1.2.3. Industry/Manufacturing 4.4.1.2.4. Residential & Commercial Heating 4.4.1.2.5. Others 4.4.1.3. United States Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 4.4.1.3.1. Fuel Cells 4.4.1.3.2. Heating 4.4.1.3.3. Feedstock 4.4.1.3.4. Power Generation 4.4.1.3.5. Others 4.4.2. Canada 4.4.2.1. Canada Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 4.4.2.1.1. Steam Methane Reforming 4.4.2.1.2. Electrolysis 4.4.2.1.3. Coal Gasification 4.4.2.1.4. Biomass Gasification 4.4.2.1.5. Others 4.4.2.2. Canada Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 4.4.2.2.1. Transportation 4.4.2.2.2. Power Generation 4.4.2.2.3. Industry/Manufacturing 4.4.2.2.4. Residential & Commercial Heating 4.4.2.2.5. Others 4.4.2.3. Canada Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 4.4.2.3.1. Fuel Cells 4.4.2.3.2. Heating 4.4.2.3.3. Feedstock 4.4.2.3.4. Power Generation 4.4.2.3.5. Others 4.4.3. Mexico 4.4.3.1. Mexico Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 4.4.3.1.1. Steam Methane Reforming 4.4.3.1.2. Electrolysis 4.4.3.1.3. Coal Gasification 4.4.3.1.4. Biomass Gasification 4.4.3.1.5. Others 4.4.3.2. Mexico Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 4.4.3.2.1. Transportation 4.4.3.2.2. Power Generation 4.4.3.2.3. Industry/Manufacturing 4.4.3.2.4. Residential & Commercial Heating 4.4.3.2.5. Others 4.4.3.3. Mexico Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 4.4.3.3.1. Fuel Cells 4.4.3.3.2. Heating 4.4.3.3.3. Feedstock 4.4.3.3.4. Power Generation 4.4.3.3.5. Others 5. Europe Hydrogen Energy Transition Market Size and Forecast by Segmentation (by Value in USD Million) 2023-2030 5.1. Europe Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 5.1. Europe Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 5.1. Europe Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 5.4. Europe Hydrogen Energy Transition Market Size and Forecast, by Country (2023-2030) 5.4.1. United Kingdom 5.4.1.1. United Kingdom Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 5.4.1.2. United Kingdom Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 5.4.1.3. United Kingdom Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 5.4.2. France 5.4.2.1. France Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 5.4.2.2. France Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 5.4.2.3. France Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 5.4.3. Germany 5.4.3.1. Germany Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 5.4.3.2. Germany Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 5.4.3.3. Germany Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 5.4.4. Italy 5.4.4.1. Italy Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 5.4.4.2. Italy Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 5.4.4.3. Italy Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 5.4.5. Spain 5.4.5.1. Spain Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 5.4.5.2. Spain Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 5.4.5.3. Spain Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 5.4.6. Sweden 5.4.6.1. Sweden Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 5.4.6.2. Sweden Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 5.4.6.3. Sweden Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 5.4.7. Austria 5.4.7.1. Austria Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 5.4.7.2. Austria Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 5.4.7.3. Austria Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 5.4.8. Rest of Europe 5.4.8.1. Rest of Europe Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 5.4.8.2. Rest of Europe Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 5.4.8.3. Rest of Europe Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 6. Asia Pacific Hydrogen Energy Transition Market Size and Forecast by Segmentation (by Value in USD Million) 2023-2030 6.1. Asia Pacific Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 6.2. Asia Pacific Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 6.3. Asia Pacific Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 6.4. Asia Pacific Hydrogen Energy Transition Market Size and Forecast, by Country (2023-2030) 6.4.1. China 6.4.1.1. China Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 6.4.1.2. China Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 6.4.1.3. China Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 6.4.2. S Korea 6.4.2.1. S Korea Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 6.4.2.2. S Korea Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 6.4.2.3. S Korea Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 6.4.3. Japan 6.4.3.1. Japan Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 6.4.3.2. Japan Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 6.4.3.3. Japan Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 6.4.4. India 6.4.4.1. India Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 6.4.4.2. India Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 6.4.4.3. India Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 6.4.5. Australia 6.4.5.1. Australia Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 6.4.5.2. Australia Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 6.4.5.3. Australia Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 6.4.6. Indonesia 6.4.6.1. Indonesia Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 6.4.6.2. Indonesia Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 6.4.6.3. Indonesia Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 6.4.7. Malaysia 6.4.7.1. Malaysia Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 6.4.7.2. Malaysia Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 6.4.7.3. Malaysia Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 6.4.8. Vietnam 6.4.8.1. Vietnam Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 6.4.8.2. Vietnam Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 6.4.8.3. Vietnam Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 6.4.9. Taiwan 6.4.9.1. Taiwan Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 6.4.9.2. Taiwan Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 6.4.9.3. Taiwan Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 6.4.10. Rest of Asia Pacific 6.4.10.1. Rest of Asia Pacific Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 6.4.10.2. Rest of Asia Pacific Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 6.4.10.3. Rest of Asia Pacific Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 7. Middle East and Africa Hydrogen Energy Transition Market Size and Forecast by Segmentation (by Value in USD Million) 2023-2030 7.1. Middle East and Africa Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 7.2. Middle East and Africa Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 7.3. Middle East and Africa Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 7.4. Middle East and Africa Hydrogen Energy Transition Market Size and Forecast, by Country (2023-2030) 7.4.1. South Africa 7.4.1.1. South Africa Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 7.4.1.2. South Africa Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 7.4.1.3. South Africa Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 7.4.2. GCC 7.4.2.1. GCC Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 7.4.2.2. GCC Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 7.4.2.3. GCC Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 7.4.3. Nigeria 7.4.3.1. Nigeria Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 7.4.3.2. Nigeria Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 7.4.3.3. Nigeria Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 7.4.4. Rest of ME&A 7.4.4.1. Rest of ME&A Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 7.4.4.2. Rest of ME&A Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 7.4.4.3. Rest of ME&A Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 8. South America Hydrogen Energy Transition Market Size and Forecast by Segmentation (by Value in USD Million) 2023-2030 8.1. South America Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 8.2. South America Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 8.3. South America Hydrogen Energy Transition Market Size and Forecast, by Application(2023-2030) 8.4. South America Hydrogen Energy Transition Market Size and Forecast, by Country (2023-2030) 8.4.1. Brazil 8.4.1.1. Brazil Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 8.4.1.2. Brazil Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 8.4.1.3. Brazil Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 8.4.2. Argentina 8.4.2.1. Argentina Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 8.4.2.2. Argentina Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 8.4.2.3. Argentina Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 8.4.3. Rest Of South America 8.4.3.1. Rest Of South America Hydrogen Energy Transition Market Size and Forecast, by Production Method (2023-2030) 8.4.3.2. Rest Of South America Hydrogen Energy Transition Market Size and Forecast, by End-Use Industry (2023-2030) 8.4.3.3. Rest Of South America Hydrogen Energy Transition Market Size and Forecast, by Application (2023-2030) 9. Global Hydrogen Energy Transition Market: Competitive Landscape 9.1. MMR Competition Matrix 9.2. Competitive Landscape 9.3. Key Players Benchmarking 9.3.1. Company Name 9.3.2. Business Segment 9.3.3. End-user Segment 9.3.4. Revenue (2023) 9.3.5. Company Locations 9.4. Leading Hydrogen Energy Transition Market Companies, by market capitalization 9.5. Market Structure 9.5.1. Market Leaders 9.5.2. Market Followers 9.5.3. Emerging Players 9.6. Mergers and Acquisitions Details 10. Company Profile: Key Players 10.1. Air Liquide SA 10.1.1. Company Overview 10.1.2. Business Portfolio 10.1.3. Financial Overview 10.1.4. SWOT Analysis 10.1.5. Strategic Analysis 10.1.6. Scale of Operation (small, medium, and large) 10.1.7. Details on Partnership 10.1.8. Regulatory Accreditations and Certifications Received by Them 10.1.9. Awards Received by the Firm 10.1.10. Recent Developments 10.2. Linde plc 10.3. Air Products and Chemicals, Inc. 10.4. Plug Power Inc. 10.5. Ballard Power Systems Inc. 10.6. McPhy Energy S.A. 10.7. Nel ASA 10.8. ITM Power plc 10.9. Hydrogenics Corporation 10.10. Mitsubishi Power, Ltd. 10.11. Siemens Energy AG 10.12. Doosan Fuel Cell America, Inc. 10.13. Cummins Inc. 10.14. FuelCell Energy, Inc. 10.15. Toshiba Energy Systems & Solutions Corporation 10.16. Ceres Power Holdings plc 10.17. Bloom Energy Corporation 10.18. FuelCell Energy Solutions GmbH 10.19. SFC Energy AG 10.20. Horizon Fuel Cell Technologies 11. Key Findings 12. Industry Recommendations 13. Hydrogen Energy Transition Market: Research Methodology 14. Terms and Glossary