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According to Stratistics MRC, the Global Solar Hydrogen Panel Market is accounted for $18.20 billion in 2024 and is expected to reach $39.30 billion by 2030 growing at a CAGR of 13.69% during the forecast period. Solar hydrogen panels, which combine photovoltaic technology with hydrogen production, represent a novel approach to the generation of renewable energy. These solar panels use light from the sun to create electricity, which powers an electrolyser that uses electrolysis to separate water into hydrogen and oxygen. Moreover, the hydrogen that is produced can be kept in storage and used as a clean fuel source for a number of purposes, such as energy storage, industrial processes, and transportation. By offering a sustainable way to produce hydrogen, this technology improves energy security in addition to helping to reduce greenhouse gas emissions.
According to the International Energy Agency (IEA), hydrogen demand could reach 120 million tonnes by 2030, with a significant portion expected to be produced from renewable sources, including solar energy. This indicates a growing market for solar hydrogen technologies.
Growth in the requirement for clean energy
The need for clean energy solutions is growing as a result of the global movement to reduce carbon footprints. Solar hydrogen panels are becoming a practical choice as nations work to fulfill their obligations under the Paris Agreement and other international climate agreements. They use solar energy to create hydrogen, a clean fuel that can be used for power generation and transportation, among other things. Additionally, the need for sustainable energy sources that can take the place of fossil fuels is what drives this demand even more.
High initial expenses
The upfront cost of installing solar hydrogen panels is one of the biggest obstacles to their widespread use. Photovoltaic cells, the apparatus used in electrolysis, and the infrastructure required for the distribution and storage of hydrogen can all be expensive. This cost constraint restricts access, especially in the residential and small-scale sectors where financial resources may be more limited. Furthermore, the current high upfront costs continue to be a major barrier to market growth, even though technological advancements are predicted to lower costs over time.
Increasing requirement for green hydrogen
The demand for green hydrogen, which is created using renewable energy sources like solar power, is being driven by the growing emphasis on lowering carbon emissions on a global scale. Solar hydrogen panels offer a practical means of producing clean hydrogen fuel as businesses look for environmentally friendly substitutes for fossil fuels. Additionally, manufacturers and developers now have the chance to invest in solar hydrogen technologies that serve industries like energy storage, transportation, and industrial processes, owing to the expanding green hydrogen market.
Threat from alternative energy sources
The market for solar hydrogen panels is highly competitive with other renewable energy technologies like photovoltaic systems and wind power. Moreover, these substitutes might have more affordable starting costs or easier implementation procedures, which would make them more alluring to customers and companies searching for environmentally friendly energy solutions. Because of this, solar hydrogen panels might find it difficult to overtake these well-established technologies in the market.
The COVID-19 pandemic had a major effect on the market for solar hydrogen panels by causing extensive supply chain disruptions and construction delays in projects because of lockdown protocols and social distancing rules. These disruptions hindered the adoption of renewable energy projects, such as solar hydrogen projects, because funds were frequently reallocated to meet critical healthcare needs during recessions. Furthermore, the pandemic also resulted in a deterioration of macroeconomic conditions, which limited the amount of capital available for investments in renewable energy and decreased demand for transportation and industrial energy, which in turn reduced the use of bioenergy and other renewable systems.
The Nano Solar Cells segment is expected to be the largest during the forecast period
It is projected that the solar hydrogen panel market will be dominated by the nanosolar cell segment. To increase their performance and efficiency, nanosolar cells use a layer of nanocrystals on a substrate. These cells benefit from their ability to efficiently harvest sunlight while minimizing material usage. They are typically made of materials like silicon, cadmium telluride (CdTe), or copper indium gallium selenide (CIGS). They are ideal for integration into solar hydrogen systems because of their special structure, which enhances light absorption and energy conversion. Moreover, nanosolar cells are becoming more and more popular as a result of the growing demand from consumers and industries for sustainable energy alternatives.
The Mobility segment is expected to have the highest CAGR during the forecast period
In the market for solar hydrogen panels, the mobility segment is anticipated to grow at the highest CAGR. The growing need for hydrogen fuel cells in transportation applications is driving this market trend because hydrogen has three times the energy density of fossil fuels. Fuel cell electric vehicles (FCEVs) are showing promise as a sustainable way to cut greenhouse gas emissions in the transportation sector. They are a viable alternative to conventional combustion engines. Additionally, automotive manufacturers and consumers find solar hydrogen panels to be appealing options due to their ability to produce hydrogen efficiently.
The Europe region has the largest market share for solar hydrogen panels due to its strict environmental laws and dedication to renewable energy. More than two-fifths of the global market share was held by Europe, where the adoption of solar hydrogen technologies was spearheaded by nations like France and Germany. The ambitious goals of the European Union, like the European Green Deal, are to transition to a carbon-neutral economy and drastically reduce greenhouse gas emissions. This has encouraged investments in the production of hydrogen from renewable sources. Furthermore, several European countries have instituted policies and incentives that facilitate research and development in the field of hydrogen technology, thereby augmenting the market's growth prospects.
The market for solar hydrogen panels is anticipated to grow at the highest CAGR in the Asia-Pacific region. Numerous factors, such as the fast urbanization rate, rising energy consumption, and the government's strong push for the adoption of renewable energy solutions, are contributing to this growth. Leading the way in this shift are nations like China and India, who are concentrating on increasing their renewable energy resources to meet growing electricity demand while addressing environmental issues. Additionally, boosting the market potential for solar hydrogen technologies is the region's dedication to cutting carbon emissions and moving toward a hydrogen-based economy.
Key players in the market
Some of the key players in Solar Hydrogen Panel market include Hydrogenics, SunHydrogen Inc, Enapter, Suzhou GH New Energy Co Ltd, Cummins, Schmid Group, Heliogen, Sunfire GmbH, Flux50, Solhyd, Nel Hydrogen and Proton OnSite.
In July 2024, SunHydrogen, Inc., the developer of a breakthrough technology to produce renewable hydrogen using sunlight and water, announced that it has entered into a joint development agreement with Honda R&D Co., LTD. SunHydrogen's innovative solar hydrogen technology uses abundant and low-cost materials, requires no external power other than sunlight, and is designed with scalability in mind.
In January 2024, Enapter AG has entered into an agreement to establish a joint venture company with Wolong Electric Group Co, Ltd, Shaoxing City, Zhejiang Province. This significantly expands the cooperation agreed in the framework agreement. Through this partnership, the joint venture will acquire stacks from the Enapter Group and then produce the Enapter AEM electrolyser products locally in China for the Chinese market.
In December 2023, Cummins Inc has reached an agreement in principle to resolve U.S. regulatory claims regarding its emissions certification and compliance process for certain engines primarily used in pick-up truck applications. The company has cooperated fully with the relevant regulators, already addressed many of the issues involved, and looks forward to obtaining certainty as it concludes this lengthy matter.