Blue Hydrogen Market Report

The growing demand for blue hydrogen is largely driven by its cost-competitiveness and ability to leverage existing natural gas infrastructure. As regions with abundant natural gas resources prioritize cleaner energy solutions, blue hydrogen presents an efficient transitional fuel. The production cost of blue hydrogen, typically ranging from US$2.8-3.5 per kg, is significantly lower compared to green hydrogen's broader cost range of US$3-6 per kg.

Additionally, blue hydrogen offers a feasible option for decarbonizing heavy industries, where immediate adoption of green hydrogen may not yet be economically viable, thus accelerating its market uptake. However, the growing consciousness of climate change and increased demand for energy sustainability are some of the significant driving forces behind the adoption of blue hydrogen. Increasing awareness among consumer groups and investors of environmental issues is also forcing companies to seek to exploit environmentally friendly sources of energy.

Blue hydrogen, as a potential fuel source, should go a long way in reducing carbon footprint. As such, the current change of regulations now provides businesses with a better position than ever to try and keep up with the global call for transition. Compliance with changing regulations, coupled with that of improving corporate reputation and competitiveness in the market, means that companies who opt for blue hydrogen are seen to be proactive when it comes to climate challenges and derive consumer support as well as interest on the part of investors.

The industrial sector, especially steel, refining, and cement, is a key user of hydrogen, which has historically been produced through methods that create considerable carbon emissions. Blue hydrogen presents an attractive low-carbon option by using natural gas alongside carbon capture and storage (CCS) technology, greatly minimizing the environmental effects. This renders it a perfect option for sectors aiming to reduce carbon emissions while preserving operational efficiency. By substituting high-emission traditional hydrogen with blue hydrogen, these sectors can reduce their carbon footprints and adhere to sustainability objectives, assisting them in achieving regulatory standards and consumer expectations for cleaner goods.

Blue hydrogen production can be integrated with renewable energy sources like wind or solar to create a more sustainable and resilient energy mix. With this hybrid model, surplus renewable electricity can be used to power up the electrolysis stage of hydrogen production along with the blending of green and blue hydrogen technologies. Such models carry several benefits such as better energy security, carbon emissions reduction, and furtherance of the transition to a low-carbon energy system. By combining both the strengths of renewable and blue hydrogen production, such integration supports maximized use of energy while furthering efforts aimed at industrial and energy sectors' decarbonization.

The expansion of hydrogen infrastructures, including pipelines, storage facilities, and refueling stations, also offers a strong growth opportunity for the blue hydrogen market. Blue hydrogen has the capability to be transported and stored, thus providing a scalable solution toward supporting broader hydrogen adoption across sectors. The most recent significant development came in January 2024 when it was announced that the US Department of Energy (DOE) is investing US$623 million in grants to enhance hydrogen fuelling infrastructure and electric vehicle charging networks across the nation. For its part, more than US$90 million in funding will be reserved for clean hydrogen fuelling projects in California, Colorado, and Texas, where medium and heavy-duty vehicles are to be targeted. This investment is likely to encourage continued development in the blue hydrogen market by making infrastructure deployment.

One of the biggest opportunities for blue hydrogen relates to heavy transport, such as heavy-duty trucks, ships, and trains. Here, hydrogen can serve as a cleaner alternative to diesel. Blue hydrogen represents a viable transition fuel, especially for regions with limited renewable energy capacity or where immediate adoption of green hydrogen is not yet feasible. Using blue hydrogen, capturing carbon streams, and building on already-existing infrastructure, can reduce the emissions of the heavy transport sector without impairing its operational efficiency. With this, it has become one of the important facilitators for the transport sector's decarbonization into the future and has helped the industries comply with the sustainability targets as well as their regulatory commitments.

• Increased investments in carbon capture and storage (CCS) technologies
• Rising government support for blue hydrogen through incentives and subsidies
• Growing demand in heavy industries like steel and chemicals for decarbonization
• Technological advancements in hydrogen production efficiency and cost reduction
• Policy-driven decarbonization targets accelerating blue hydrogen adoption

The processes involved in blue hydrogen production are very hazardous to the environment and health, mainly because of hazardous chemicals, potential methane leaks, and problems associated with CO₂ management. Blue hydrogen involves extracting fossil fuels, namely shale gas, which requires increased hydraulic fracturing in already heavily industrialized areas. Hence, the enhanced production results in increased emissions of poisonous heavy metals and particulate matter, such as fine particulate matter (PM2.5), volatile organic compounds (VOCs), polycyclic aromatic hydrocarbons (PAHs), glycol, and radium. They are known to increase the risk of all of the following within the local communities: respiratory conditions like asthma and cardiovascular diseases, birth defects, mental health issues, and even cancer. Such health and environmental concerns are a huge barrier to the large-scale deployment of blue hydrogen as a clean source of energy.

The competition from green hydrogen has been rising with the further development of solar and wind technologies and a continuing falling price. Renewable energy prices have been decreasing, and green hydrogen is getting more attractive as fuel. Moreover, it is an alternative potential source compared to blue hydrogen, presumably cheaper and definitely more sustainable. With the further scaling up of green hydrogen production and increasing its economic feasibility, the interest in production grows in regions that have a greater share of renewable resources. This could lead to reduced demand for blue hydrogen, as industries and governments seek cleaner and less expensive sources to use within their decarbonization plans.

The limited scale of the current commercial CCS projects makes this a challenge in the production of blue hydrogen since, so far, infrastructure is not large enough to accommodate global demand for hydrogen. As reflected by the Global CCS Institute, there are so far 41 operational CCS projects and 351 in development on the global scale. While growth is occurring, the growth rate remains insufficient to support large-scale production levels of widespread blue hydrogen. This lack in capacity of CCS therefore can be considered a limiting factor that may potentially slow the scaling of blue hydrogen to become a viable low-carbon energy solution within coming years.

The blue hydrogen market highlights the growing investment and strategic initiatives aimed at scaling its production. In November 2023, Air Products revealed its plans to construct, possess, and manage an advanced carbon capture and CO2 processing facility at its current hydrogen production location in Rotterdam, the Netherlands. Scheduled to be operational by 2026, the facility will generate blue hydrogen to serve ExxonMobil’s Rotterdam refinery, as well as other clients via Air Products' hydrogen pipeline system. Upon completion, this plant will be the largest blue hydrogen facility in Europe, representing a crucial step in the region's shift towards cleaner energy.

Awards are very significant because they give reinforcement to innovation in the blue hydrogen sector, as awards do credit cutting-edge projects and breakthroughs. Forcing companies to stretch their technology for more efficiency, as well as less cost involved in hydrogen production, carbon capture, and storage (CCS), competition between companies to win prestigious awards is a prime example in the United States Recently, the Appalachian Regional Clean Hydrogen Hub (ARCH2) won the award from the US Department of Energy in July 2024, pledging a US$30 million fund to support its blue and green hydrogen projects. This marks the beginning of one of the biggest initiatives for hydrogen in the US and the rising momentum that continues to drive the development of technologies in hydrogen.

In August 2024, Shell collaborated with Wood to offer pre-FEED services for the bold "Blue Horizons" initiative in Oman. This innovative project seeks to generate low-carbon blue hydrogen and ammonia for regional and global markets, all while capturing and sequestering CO2 from the manufacturing process. The initiative, anticipated to be the first of its kind in Oman, will include a comprehensive facility for the production of blue hydrogen and ammonia, along with marine infrastructure for ammonia storage, a 200-kilometer pipeline, and CO2 injection systems. This partnership highlights the significance of collaborations in enhancing blue hydrogen production and promoting the energy transition.

The United States and Canada are becoming important countries in the blue hydrogen market, fueled by substantial investments and strategic efforts. The U.S. government is actively promoting hydrogen production via grants and tax incentives, especially for carbon capture and storage (CCS) as well as hydrogen technologies. California plans to deploy 1.5 million zero-emission vehicles by 2025 and considers hydrogen fuel cell electric vehicles essential for achieving its clean transportation objectives. Moreover, expansive CCS initiatives such as Project Tundra, which emphasizes hydrogen and carbon capture, are acquiring momentum. Key industry leaders like ExxonMobil, Chevron, and Air Products are significantly investing in blue hydrogen initiatives. These joint initiatives are establishing North America as a leading area in the worldwide blue hydrogen market.

Europe has the potential to be one of the fastest-growing regions for the market, with the likes of Germany, the Netherlands, and the United Kingdom making rapid strides in terms of hydrogen development. The region benefits from strong policy support that is being aimed at helping towards the elusive goal of decarbonization, particularly tied up in the EU's commitment to climate neutrality by 2050. This also involves a hydrogen strategy incorporating both blue and green hydrogen. In October 2024, the UK government committed to a massive funding program for carbon capture and storage, worth GBP 21.7 billion over 25 years. Germany, the largest economy in Europe, aims at net zero by 2045, bringing another wave of demand for clean hydrogen solutions.

As reported in November 2023, Equinor's proposed pipeline project will deliver blue hydrogen-perhaps more accurately known as hydrogen produced from fossil directly into Europe. That is to say, it will draw on hydrogen produced at two large-scale Norwegian facilities, one of which is being developed by Shell. Altogether, this is a combination that should place Europe firmly in the vanguard of the growing blue hydrogen market.

The report provides a detailed overview of the blue hydrogen market insights in regions including North America, Latin America, Europe, Asia-Pacific, and the Middle East and Africa. The country-specific assessment for the blue hydrogen market has been offered for all regional market shares, along with forecasts, market scope estimates, price point assessment, and impact analysis of prominent countries and regions. Throughout this market research report, Y-o-Y growth and CAGR estimates are also incorporated for every country and region, to provide a detailed view of the blue hydrogen market. These Y-o-Y projections on regional and country-level markets brighten the political, economic, and business environment outlook, which is anticipated to have a substantial impact on the growth of the blue hydrogen market. Some key countries and regions included in the blue hydrogen market report are as follows:

• Blue hydrogen market detailed segments and segment-wise market breakdown
• Blue hydrogen market dynamics (Recent industry trends, drivers, restraints, growth potential, opportunities in blue hydrogen industry)
• Current, historical, and forthcoming 10 years market valuation in terms of blue hydrogen market size (US$ Mn), volume (Tons), share (%), Y-o-Y growth rate, CAGR (%) analysis
• Blue hydrogen market demand analysis
• Blue hydrogen market pricing analysis over the forecast period (by key segment and by region)
• Blue hydrogen market regional insights with the region-wise market breakdown
• Competitive analysis – key companies profiling including their market share, product offerings, and competitive strategies.
• Latest developments and innovations in the blue hydrogen market
• Regulatory landscape by key regions and key countries
• Supply Chain and Value Chain Analysis in the Blue Hydrogen Market
• Blue hydrogen market sales and distribution strategies
• A comprehensive overview of the parent market
• A detailed viewpoint on the blue hydrogen market forecast by countries
• Mergers and acquisitions in the blue hydrogen market
• Essential information to enhance market position
• Robust research methodology