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Pages: 200 |
Jan 2022 |
The global hydrogen generation market size was $126,200.0 million in 2020 and is predicted to grow with a CAGR of 6.9%, by generating a revenue of $212,877.4 million by 2028.
Hydrogen generation market is gaining huge demand owing to the use of hydrogen as a carrier. This energy carrier facilitates transport of energy from one place to another. Also, hydrogen can be generated from various sources such as biomass, water, fossil fuel, and others. Hydrogen generation technology is becoming popular as hydrogen has highest energy content than any other fuel by weight. For instance, the energy content by weight in hydrogen is three times more than that of gasoline. Due to this factor, hydrogen is used as a rocket fuel and in fuel cells to generate electricity for spacecrafts.
However, hydrogen storage systems are more expensive compared to natural gas storage systems. This is majorly owing to weight and volume of hydrogen storage systems which are too high that leads to inadequate vehicle range compared to petroleum fueled vehicles. This factor is anticipated to restrain the hydrogen generation market size during the forecast period.
The development of advanced electrolysis technologies to enhance the scalability of hydrogen production units is estimated to generate huge growth opportunities. For instance, proton exchange membrane or polymer electrolyte membrane (PEM) electrolyzers can be used for residential as well as industrial purpose. Such advanced electrolysis technology is favored as it helps in reducing the operating expenses and capital expenditures required for hydrogen generation.
According to regional analysis, the Asia-Pacific hydrogen generation market accounted for $53,483.6 million in 2020 and is predicted to grow with a CAGR of 7.5% in the projected timeframe.
Hydrogen generation refers to various methods of producing hydrogen via different processes such as steam methane reforming electrolysis and others. Hydrogen is used in synthesis of ammonia and for manufacturing of nitrogenous fertilizers. Also, it can be used for manufacturing of methanol and as a rocket fuel in various space research activities. Hydrogen is a clean fuel, its production does not emit harmful carbon dioxide due to which it helps in decarbonizing the economy and achieving climate neutrality goals.
The COVID-19 pandemic had a major impact on hydrogen generation market globally. This is majorly owing to reduced investment in new energy sector which has slowed down the expansion of clean energy technologies. For instance, as stated on June 11, 2020, the International Energy Agency, the Paris-based intergovernmental organization, only 6 out of 46 technologies working on clean energy transformation were on track to meet the sustainability goals in 2019. Owing to complete lockdown imposed across various countries, the global energy demand declined by sharp 25% and in the countries with partial lockdown restrictions, the energy demand was declined by almost 18%. Hence, lower capital spending, supply chain disruptions, and economic downturn brought by the COVID-19 pandemic have negatively impacted hydrogen generation market share.
Various hydrogen projects announced in 2020 is estimated to help the economy and clean energy initiatives back on track. For instance, in November 2020, China announced a 15-year strategy for new energy vehicles for developing fuel cell technology for hydrogen-powered buses and trucks. China is already a leading country in government-sponsored hydrogen research and development projects. In addition, the Singaporean and Australian governments have signed a memorandum of understanding in October 2020 regarding low emissions technology. Also, Singapore announced $49 million towards low-carbon research funding initiative in October 2020.
At present the global hydrogen generation is primarily dependent on fossil fuels and technologies such as steam methane reforming and coal gasification. However, these technologies lead to emission of harmful greenhouse gases. Hence, CCUS technology is being incorporated as it reduces environmental impact and increases the sustainability of the process. CCUS technology is incorporated for large scale hydrogen production to reduce the carbon emissions. For instance, the carbon generated during CCUS can be utilized for production of fertilizers and for enhanced oil recovery (EOR). For instance, Susteon, the U.S.-based startup company, is actively working towards production of blue hydrogen using CCUS technology. The company has developed compact distributed H2 generators to produce high-purity pressurized hydrogen while capturing carbon dioxide. The company uses catalytic nonthermal plasma that activates methane for the production of syngas. This syngas is purified and compressed to produce high-purity, high-pressure carbon-free hydrogen.
To know more about global hydrogen generation market drivers, get in touch with our analysts here.
Hydrogen can be stored either as a gas in high-pressure tanks or it can be stored as a liquid in cryogenic temperatures. However, this hydrogen must be in gaseous form to be used as a fuel cell. This method of hydrogen storage leads to inherent loss of energy as compressing hydrogen utilizes 13% of total energy content by itself and if it is liquified, then it loses about 40% of energy. Hence, setting up the necessary infrastructure required for hydrogen fuel cells requires large capital investment. These factors are anticipated to restrain the hydrogen generation market size during the analysis timeframe.
Hydrogen has wide range of applications across various sectors. For instance, hydrogen can be used for clean transportation in fuel cell that generates electricity directly onboard a vehicle with an electric engine. These vehicles are “zero-emission” vehicles as they release only water as a by-product. Also, in energy sector, hydrogen can be used to produce clean and silent energy. This energy can be used as back-up energy systems, for portable power generators, and as a captive fleet. Similarly, in space industry hydrogen can be used as a rocket fuel as it concentrated most of the energy. For instance, 1 kg of hydrogen has 3 times more energy than 1 kg of gasoline. This is an important factor as launcher in space industry must be as light as possible. Also, stationary hydrogen fuel cells can be used to provide uninterrupted power supply to data centers and hospitals. It can be used to power telecommunications in remote locations and as backup power for regional emergency shelters.
To know more about global hydrogen generation market opportunities, get in touch with our analysts here.
[SOURCEGRAPH]
Source: Research Dive Analysis
The blue sub-type is anticipated to have a dominant market share and generate a revenue of $108,146.9 million by 2028, growing from $64,661.2 million in 2020. Blue hydrogen is produced from natural gas via steam reforming process in which natural gas is mixed with hot stream and a catalyst. Blue hydrogen is a low-carbon fuel which can be used for power generation, heating buildings, powering cars & trucks, and others. In blue hydrogen, the CO2 which is produced does not escape into the environment. Instead, this CO2 is captured at the production site and stored separately. This technology is known as carbon capture and storage (CCS) which helps in reducing the carbon emission into the atmosphere. Hence, it is environmentally friendly compared to gray hydrogen, but blue hydrogen adds up the carbon storage cost.
The green sub-type is anticipated to show the fastest growth and generate a revenue of $46,381.6 million by 2028, growing from $25,949.0 million in 2020. Green hydrogen is gaining huge popularity as it is produced from renewable energy sources such as wind energy which is environmentally friendly. Green hydrogen stabilizes heat supply & electricity as green hydrogen can be converted into electricity and heat and can be used for electricity supply & domestic energy. Green hydrogen supports global transition in sustainable energy and net zero carbon emissions. It has unprecedented momentum to meet the global hydrogen demand as clean energy solution. Also, major investments in green hydrogen technology are anticipated to drive the green hydrogen demand. For instance, the European Union (EU) has planned to invest $430 million in green hydrogen projects by 2030.
[TYPEGRAPH]
Source: Research Dive Analysis
The merchant hydrogen generation sub-segment is anticipated to have a dominant market share and generate a revenue of $138,331.3 million by 2028, growing from $80,101.7 million in 2020. In merchant hydrogen type, the hydrogen is produced for delivery to other locations as an industrial gas. The merchant hydrogen production and distribution are beneficial for various end-use industries such as oil & gas. For instance, merchant hydrogen is used in the manufacturing of gasoline, plastics, metals, jet fuel, and agricultural fertilizers. In addition, merchant hydrogen is also used in food oil products and in pharmaceutical industry. Though the present market for merchant hydrogen is small, its emerging application in fuel for transportation is anticipated to gain huge popularity in the upcoming years.
[TECHNOLOGYGRAPH]
Source: Research Dive Analysis
Steam methane reforming sub-segment is anticipated to have a dominant market share and generate a revenue of $116,915.4 million by 2028, growing from $66,741.6 million in 2020. Steam methane reforming is a process in which natural gas or methane stream such as landfill gas or biogas is reacted with steam in presence of catalyst to produce hydrogen. This process is widely used for hydrogen generation at present, however it leads to the emission of carbon dioxide. Steam methane reforming produces hydrogen rich gas with 70-75% hydrogen on dry mass basis. When natural gas is used in steam methane reforming process, the efficiency of hydrogen produced is 72% on a lower heating value basis. Based on feedstock, the cost of hydrogen and scale of production varies.
[APPLICATIONGRAPH]
Source: Research Dive Analysis
The oil refining sub-segment is anticipated to have a dominant market share and generate a revenue of $87,682.7 million by 2028, growing from $49,313.4 million in 2020. Hydrogen is widely used for oil refining to lower the sulfur content of the diesel fuel. Growing demand for fuel from transportation and power generation sector, both domestically and internationally has increased the demand for hydrogen in the oil refining sector. Also, to meet the growing demand for hydrogen at oil refineries, hydrogen is purchased from merchant suppliers rather than producing hydrogen on-site at the refinery. Moreover, at present, most of the oil refineries meet their hydrogen demand via steam methane reforming process of hydrogen production.
[ENDUSEINDUSTRYGRAPH]
Source: Research Dive Analysis
The transportation sub-segment is anticipated to have a dominant market share and generate a revenue of $132,592.9 million by 2028, growing from $76,445.7 million in 2020. Hydrogen can be used as a fuel in transportation sector and it offers same long driving range as that of conventional fuels. The use of hydrogen in transportation helps in decarbonizing the transportation sector. This is because the use of hydrogen as a fuel has zero emissions, and it only produces water vapor as a byproduct. For instance, fuel cell uses hydrogen to generate electricity onboard the vehicle via chemical process without combustion. For instance, the leading automotive manufacturers namely Honda, Toyota, and Hyundai have already sold many fuel cell electric vehicles (FCEV) in the U.S., and other automotive companies are planning to produce their own FCEVs in coming years. Also, many fuel cell buses are operating in the U.S. that offers clean and reliable transportation along with reducing the maintenance costs.
[REGIONGRAPH]
Source: Research Dive Analysis
The Asia-Pacific hydrogen generation market accounted $53,483.6 million in 2020 and is projected to grow with a CAGR of 7.5%. Asia-Pacific is a world leader in hydrogen market owing to announcements of new hydrogen projects and growing investments in clean energy sector. For instance, in August 2021, China approved renewable mega-project for green hydrogen in the Chinese region of Inner Mongolia. This project aims to utilize solar and wind power for producing green hydrogen and to achieve net zero emission goal. The Inner Mongolia’a Energy Administration has approved cluster of hydrogen plants in Ordos and Baotou. These plants will utilize 370 megawatts of wind and 1.85 gigawatts of solar for production of 66,900 tons of green hydrogen. Also, in Japan, hydrogen is an important sector that helps in decarbonizing the economy. In addition, hydrogen is among 14 sectors that comes under the Green Growth Strategy Through Achieving Carbon Neutrality in 2050 which was announced in December 2020. Also, India is all set to install its first green hydrogen-based energy storage project in Simhadri, Andhra Pradesh. These factors are anticipated to drive the Asia-Pacific hydrogen generation market share during the forecast period.
Source: Research Dive Analysis
Some of the leading hydrogen generation market players are Air Liquide S.A., Cummins Inc., Linde plc, Air Products and Chemicals, Inc., Iwatani Corporation, Engie SA, ITM Power plc, Messer Group, Showa Denko, and Uniper SE.
Porter’s Five Forces Analysis for the Global Hydrogen Generation Market:
Aspect | Particulars |
Historical Market Estimations | 2019-2020 |
Base Year for Market Estimation | 2020 |
Forecast Timeline for Market Projection | 2021-2028 |
Geographical Scope | North America, Europe, Asia-Pacific, LAMEA |
Segmentation by Source |
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Segmentation by Type |
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Segmentation by Technology |
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Segmentation by Application |
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Segmentation by End-use Industry |
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Key Companies Profiled |
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1.Research Methodology
1.1.Desk Research
1.2.Real time insights and validation
1.3.Forecast model
1.4.Assumptions and forecast parameters
1.4.1.Assumptions
1.4.2.Forecast parameters
1.5.Data sources
1.5.1.Primary
1.5.2.Secondary
2.Executive Summary
2.1.360° summary
2.2.Source trends
2.3.Type trends
2.4.Technology trends
2.5.Application trends
2.6.End-use Industry trends
3.Market overview
3.1.Market segmentation & definitions
3.2.Key takeaways
3.2.1.Top investment pockets
3.2.2.Top winning strategies
3.3.Porter’s five forces analysis
3.3.1.Bargaining power of consumers
3.3.2.Bargaining power of suppliers
3.3.3.Threat of new entrants
3.3.4.Threat of substitutes
3.3.5.Competitive rivalry in the market
3.4.Market dynamics
3.4.1.Drivers
3.4.2.Restraints
3.4.3.Opportunities
3.5.Technology landscape
3.6.Regulatory landscape
3.7.Patent landscape
3.8.Market value chain analysis
3.9.Strategic overview
4.Hydrogen Generation Market, by Source
4.1.Blue
4.1.1.Key market trends, growth factors, and opportunities
4.1.2.Market size and forecast, by region, 2020-2028
4.1.3.Market share analysis, by country, 2020 & 2028
4.2.Gray
4.2.1.Key market trends, growth factors, and opportunities
4.2.2.Market size and forecast, by region, 2020-2028
4.2.3.Market share analysis, by country, 2020 & 2028
4.3.Green
4.3.1.Key market trends, growth factors, and opportunities
4.3.2.Market size and forecast, by region, 2020-2028
4.3.3.Market share analysis, by country, 2020 & 2028
5.Hydrogen Generation Market, by Type
5.1.Merchant
5.1.1.Key market trends, growth factors, and opportunities
5.1.2.Market size and forecast, by region, 2020-2028
5.1.3.Market share analysis, by country, 2020 & 2028
5.2.Captive
5.2.1.Key market trends, growth factors, and opportunities
5.2.2.Market size and forecast, by region, 2020-2028
5.2.3.Market share analysis, by country, 2020 & 2028
6.Hydrogen Generation Market, by Technology
6.1.Steam Methane Reforming
6.1.1.Key market trends, growth factors, and opportunities
6.1.2.Market size and forecast, by region, 2020-2028
6.1.3.Market share analysis, by country, 2020 & 2028
6.2.Coal Gasification
6.2.1.Key market trends, growth factors, and opportunities
6.2.2.Market size and forecast, by region, 2020-2028
6.2.3.Market share analysis, by country, 2020 & 2028
6.3.Others
6.3.1.Key market trends, growth factors, and opportunities
6.3.2.Market size and forecast, by region, 2020-2028
6.3.3.Market share analysis, by country, 2020 & 2028
7.Hydrogen Generation Market, by Application
7.1.Oil Refining
7.1.1.Key market trends, growth factors, and opportunities
7.1.2.Market size and forecast, by region, 2020-2028
7.1.3.Market share analysis, by country, 2020 & 2028
7.2.Chemical Processing
7.2.1.Key market trends, growth factors, and opportunities
7.2.2.Market size and forecast, by region, 2020-2028
7.2.3.Market share analysis, by country, 2020 & 2028
7.3.Iron and Steel Production
7.3.1.Key market trends, growth factors, and opportunities
7.3.2.Market size and forecast, by region, 2020-2028
7.3.3.Market share analysis, by country, 2020 & 2028
7.4.Others
7.4.1.Key market trends, growth factors, and opportunities
7.4.2.Market size and forecast, by region, 2020-2028
7.4.3.Market share analysis, by country, 2020 & 2028
8.Hydrogen Generation Market, by End-use Industry
8.1.Transportation
8.1.1.Key market trends, growth factors, and opportunities
8.1.2.Market size and forecast, by region, 2020-2028
8.1.3.Market share analysis, by country, 2020 & 2028
8.2.Power Generation
8.2.1.Key market trends, growth factors, and opportunities
8.2.2.Market size and forecast, by region, 2020-2028
8.2.3.Market share analysis, by country, 2020 & 2028
8.3.Buildings
8.3.1.Key market trends, growth factors, and opportunities
8.3.2.Market size and forecast, by region, 2020-2028
8.3.3.Market share analysis, by country, 2020 & 2028
9.Hydrogen Generation Market, by Region
9.1.North America
9.1.1.Key market trends, growth factors, and opportunities
9.1.2.Market size and forecast, by Source, 2020-2028
9.1.3.Market size and forecast, by Type, 2020-2028
9.1.4.Market size and forecast, by Technology, 2020-2028
9.1.5.Market size and forecast, by Application, 2020-2028
9.1.6.Market size and forecast, by End-use Industry, 2020-2028
9.1.7.Market size and forecast, by country, 2020-2028
9.1.8.U.S.
9.1.8.1.Market size and forecast, by Source, 2020-2028
9.1.8.2.Market size and forecast, by Type, 2020-2028
9.1.8.3.Market size and forecast, by Technology, 2020-2028
9.1.8.4.Market size and forecast, by Application, 2020-2028
9.1.8.5.Market size and forecast, by End-use Industry, 2020-2028
9.1.9.Canada
9.1.9.1.Market size and forecast, by Source, 2020-2028
9.1.9.2.Market size and forecast, by Type, 2020-2028
9.1.9.3.Market size and forecast, by Technology, 2020-2028
9.1.9.4.Market size and forecast, by Application, 2020-2028
9.1.9.5.Market size and forecast, by End-use Industry, 2020-2028
9.1.10.Mexico
9.1.10.1.Market size and forecast, by Source, 2020-2028
9.1.10.2.Market size and forecast, by Type, 2020-2028
9.1.10.3.Market size and forecast, by Technology, 2020-2028
9.1.10.4.Market size and forecast, by Application, 2020-2028
9.1.10.5.Market size and forecast, by End-use Industry, 2020-2028
9.2.Europe
9.2.1.Key market trends, growth factors, and opportunities
9.2.2.Market size and forecast, by Source, 2020-2028
9.2.3.Market size and forecast, by Type, 2020-2028
9.2.4.Market size and forecast, by Technology, 2020-2028
9.2.5.Market size and forecast, by Application, 2020-2028
9.2.6.Market size and forecast, by End-use Industry, 2020-2028
9.2.7.Market size and forecast, by country, 2020-2028
9.2.8.Germany
9.2.8.1.Market size and forecast, by Source, 2020-2028
9.2.8.2.Market size and forecast, by Type, 2020-2028
9.2.8.3.Market size and forecast, by Technology, 2020-2028
9.2.8.4.Market size and forecast, by Application, 2020-2028
9.2.8.5.Market size and forecast, by End-use Industry, 2020-2028
9.2.9.UK
9.2.9.1.Market size and forecast, by Source, 2020-2028
9.2.9.2.Market size and forecast, by Type, 2020-2028
9.2.9.3.Market size and forecast, by Technology, 2020-2028
9.2.9.4.Market size and forecast, by Application, 2020-2028
9.2.9.5.Market size and forecast, by End-use Industry, 2020-2028
9.2.10.France
9.2.10.1.Market size and forecast, by Source, 2020-2028
9.2.10.2.Market size and forecast, by Type, 2020-2028
9.2.10.3.Market size and forecast, by Technology, 2020-2028
9.2.10.4.Market size and forecast, by Application, 2020-2028
9.2.10.5.Market size and forecast, by End-use Industry, 2020-2028
9.2.11.Italy
9.2.11.1.Market size and forecast, by Source, 2020-2028
9.2.11.2.Market size and forecast, by Type, 2020-2028
9.2.11.3.Market size and forecast, by Technology, 2020-2028
9.2.11.4.Market size and forecast, by Application, 2020-2028
9.2.11.5.Market size and forecast, by End-use Industry, 2020-2028
9.2.12.Spain
9.2.12.1.Market size and forecast, by Source, 2020-2028
9.2.12.2.Market size and forecast, by Type, 2020-2028
9.2.12.3.Market size and forecast, by Technology, 2020-2028
9.2.12.4.Market size and forecast, by Application, 2020-2028
9.2.12.5.Market size and forecast, by End-use Industry, 2020-2028
9.2.13.Rest of Europe9.2.13.1.Market size and forecast, by Source, 2020-2028
9.2.13.2.Market size and forecast, by Type, 2020-2028
9.2.13.3.Market size and forecast, by Technology, 2020-2028
9.2.13.4.Market size and forecast, by Application, 2020-2028
9.2.13.5.Market size and forecast, by End-use Industry, 2020-2028
9.3.Asia Pacific
9.3.1.Key market trends, growth factors, and opportunities
9.3.2.Market size and forecast, by Source, 2020-2028
9.3.3.Market size and forecast, by Type, 2020-2028
9.3.4.Market size and forecast, by Technology, 2020-2028
9.3.5.Market size and forecast, by Application, 2020-2028
9.3.6.Market size and forecast, by End-use Industry, 2020-2028
9.3.7.Market size and forecast, by country, 2020-2028
9.3.8.China
9.3.8.1.Market size and forecast, by Source, 2020-2028
9.3.8.2.Market size and forecast, by Type, 2020-2028
9.3.8.3.Market size and forecast, by Technology, 2020-2028
9.3.8.4.Market size and forecast, by Application, 2020-2028
9.3.8.5.Market size and forecast, by End-use Industry, 2020-2028
9.3.9.Japan
9.3.9.1.Market size and forecast, by Source, 2020-2028
9.3.9.2.Market size and forecast, by Type, 2020-2028
9.3.9.3.Market size and forecast, by Technology, 2020-2028
9.3.9.4.Market size and forecast, by Application, 2020-2028
9.3.9.5.Market size and forecast, by End-use Industry, 2020-2028
9.3.10.India
9.3.10.1.Market size and forecast, by Source, 2020-2028
9.3.10.2.Market size and forecast, by Type, 2020-2028
9.3.10.3.Market size and forecast, by Technology, 2020-2028
9.3.10.4.Market size and forecast, by Application, 2020-2028
9.3.10.5.Market size and forecast, by End-use Industry, 2020-2028
9.3.11.South Korea
9.3.11.1.Market size and forecast, by Source, 2020-2028
9.3.11.2.Market size and forecast, by Type, 2020-2028
9.3.11.3.Market size and forecast, by Technology, 2020-2028
9.3.11.4.Market size and forecast, by Application, 2020-2028
9.3.11.5.Market size and forecast, by End-use Industry, 2020-2028
9.3.12.Australia
9.3.12.1.Market size and forecast, by Source, 2020-2028
9.3.12.2.Market size and forecast, by Type, 2020-2028
9.3.12.3.Market size and forecast, by Technology, 2020-2028
9.3.12.4.Market size and forecast, by Application, 2020-2028
9.3.12.5.Market size and forecast, by End-use Industry, 2020-2028
9.3.13.Rest of Asia Pacific
9.3.13.1.Market size and forecast, by Source, 2020-2028
9.3.13.2.Market size and forecast, by Type, 2020-2028
9.3.13.3.Market size and forecast, by Technology, 2020-2028
9.3.13.4.Market size and forecast, by Application, 2020-2028
9.3.13.5.Market size and forecast, by End-use Industry, 2020-2028
9.4.LAMEA
9.4.1.Key market trends, growth factors, and opportunities
9.4.2.Market size and forecast, by Source, 2020-2028
9.4.3.Market size and forecast, by Type, 2020-2028
9.4.4.Market size and forecast, by Technology, 2020-2028
9.4.5.Market size and forecast, by Application, 2020-2028
9.4.6.Market size and forecast, by End-use Industry, 2020-2028
9.4.7.Market size and forecast, by country, 2020-2028
9.4.8.Latin America
9.4.8.1.Market size and forecast, by Source, 2020-2028
9.4.8.2.Market size and forecast, by Type, 2020-2028
9.4.8.3.Market size and forecast, by Technology, 2020-2028
9.4.8.4.Market size and forecast, by Application, 2020-2028
9.4.8.5.Market size and forecast, by End-use Industry, 2020-2028
9.4.9.Middle East
9.4.9.1.Market size and forecast, by Source, 2020-2028
9.4.9.2.Market size and forecast, by Type, 2020-2028
9.4.9.3.Market size and forecast, by Technology, 2020-2028
9.4.9.4.Market size and forecast, by Application, 2020-2028
9.4.9.5.Market size and forecast, by End-use Industry, 2020-2028
9.4.10.Africa
9.4.10.1.Market size and forecast, by Source, 2020-2028
9.4.10.2.Market size and forecast, by Type, 2020-2028
9.4.10.3.Market size and forecast, by Technology, 2020-2028
9.4.10.4.Market size and forecast, by Application, 2020-2028
9.4.10.5.Market size and forecast, by End-use Industry, 2020-2028
10.Company profiles
10.1.Air Liquide S.A.
10.1.1.Company overview
10.1.2.Operating business segments
10.1.3.Product portfolio
10.1.4.Financial performance
10.1.5.Key strategy moves and development
10.2.Cummins Inc.
10.2.1.Company overview
10.2.2.Operating business segments
10.2.3.Product portfolio
10.2.4.Financial performance
10.2.5.Key strategy moves and development
10.3.Linde plc
10.3.1.Company overview
10.3.2.Operating business segments
10.3.3.Product portfolio
10.3.4.Financial performance
10.3.5.Key strategy moves and development
10.4.Air Products and Chemicals, Inc.
10.4.1.Company overview
10.4.2.Operating business segments
10.4.3.Product portfolio
10.4.4.Financial performance
10.4.5.Key strategy moves and development
10.5.Iwatani Corporation
10.5.1.Company overview
10.5.2.Operating business segments
10.5.3.Product portfolio
10.5.4.Financial performance
10.5.5.Key strategy moves and development
10.6.Engie SA
10.6.1.Company overview
10.6.2.Operating business segments
10.6.3.Product portfolio
10.6.4.Financial performance
10.6.5.Key strategy moves and development
10.7.ITM Power plc
10.7.1.Company overview
10.7.2.Operating business segments
10.7.3.Product portfolio
10.7.4.Financial performance
10.7.5.Key strategy moves and development
10.8.Messer Group
10.8.1.Company overview
10.8.2.Operating business segments
10.8.3.Product portfolio
10.8.4.Financial performance
10.8.5.Key strategy moves and development
10.9.Showa Denko
10.9.1.Company overview
10.9.2.Operating business segments
10.9.3.Product portfolio
10.9.4.Financial performance
10.9.5.Key strategy moves and development
10.10.Uniper SE
10.10.1.Company overview
10.10.2.Operating business segments
10.10.3.Product portfolio
10.10.4.Financial performance
10.10.5.Key strategy moves and development
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