Hydrogen has emerged as a pivotal energy carrier in the global transition toward sustainable energy systems. This study analyses current trends, sectoral dynamics, and future
After modest progress for the low-carbon hydrogen and ammonia sectors in 2024 the pace looks set to pick up in 2025 – but what surprises might be in store? Read our predictions for the upcoming year.
Hydrogen storage is pivotal in the hydrogen industry chain by buffering the extensive hydrogen production from upstream and stabilizing the downstream hydrogen supply, underpinning the global efforts against
Opinion Predictions for energy and natural resources in 2025 The impact of Chinese EVs, ambitious NOCs, the Saudi storage boom and more, as Wood Mackenzie
Hydrogen energy has been proposed as a reliable and sustainable source of energy which could play an integral part in demand for foreseeable environmentally friendly
Hydrogen plays an increasingly important role in the world''s carbon neutrality, but due to the high cost of storage, underground hydrogen storage (UHS) especially in
Energy outlook 2025: emerging trends and predictions for the power industry Geopolitics, supply chains, energy storage, EVs, nuclear and hydrogen are the key themes expected to shape the global power landscape in 2025.
Long-duration energy storage (LDES): Regardless of the trajectory of these policy and technology outcomes, green hydrogen would retain its primary use case in the power sector as LDES, among other emerging storage
At the same time, future technological developments of alternatives (for instance, high-temperature electric furnaces, long-duration energy storage, and availability of biobased feedstock) could also create
Clean power systems are in high demand, offering a bright future for hydrogen and renewables. However, energy storage projects that may look promising today could be less attractive as more...
Its adoption in new applications where hydrogen should play a key role in the clean energy transition – heavy industry, long-distance transport and energy storage – accounts for less than 1% of global demand, despite 40%
Research in green hydrogen production is advancing through photocatalysis and electrocatalysis, but storage remains a challenge. Promising hydrogen carriers, such as
Therefore, this review compares the hydrogen energy roadmaps and strategies of different countries, provides an overview of the current status and technological bottlenecks of various
Green hydrogen has the potential to replace fossil fuels in the energy sector and to meet environmental goals with zero-carbon emission. One of key enabling technologies for
From 0.5 million metric tons (Mt) of capacity online today, annual low-carbon hydrogen supply could grow 30x by 2030. Only around 30% of all currently announced supply
After modest progress for the low-carbon hydrogen and ammonia sectors in 2024 the pace looks set to pick up in 2025 – but what surprises might be in store? Read our
Furthermore, Trump is likely to favour natural gas production and Carbon Capture and Storage (CCS) over extensive support for expensive electrolysers. So blue hydrogen is likely to dominate green
One of the most important methods, solid-state hydrogen storage, is widely regarded as a promising choice for future energy storage due to its excellent safety performance and high hydrogen storage capacity.
To replace petroleum-based jet fuel or marine fuel, hydrogen or hydrogen-derived fuels like ammonia may be a contender. But based on our analysis, barring some
From 0.5 million metric tons (Mt) of capacity online today, annual low-carbon hydrogen supply could grow 30x by 2030. Only around 30% of all currently announced supply for commissioning by the end of the
These formations offer high-capacity storage solutions, with salt caverns capable of holding up to 6 TWh of hydrogen and depleted gas reservoirs exceeding 1 TWh per site.
This growth trajectory reflects the increasing recognition of hydrogen storage as a vital element in sustainable energy systems, particularly as nations worldwide intensify their efforts to reduce carbon
Comprehensive analysis of the global hydrogen energy storage market, projected to grow at 6.8% CAGR from USD 18B in 2024 to USD 30.4B by 2032. Explore
Explore the promising future of hydrogen in 2025. Discover how hydrogen is emerging as a climate-friendly fuel alternative with significant growth potential.
Aspect Potential solutions Future prospects Production - Scaling up electrolysis using renewable energy sources (green hydrogen) - Widespread adoption of green hydrogen
This review paper delves into the advancements in hydrogen (H2) storage technology, a key area in the quest for sustainable energy solutions. The paper, aided by artificial intelligence, evaluates these
In this briefing, we summarise the latest key hydrogen announcements and developments in the UK, and highlight what’s next for hydrogen in the UK in 2025.
These global initiatives and auctions demonstrate a commitment to driving hydrogen and ammonia adoption in the energy sector, laying the foundation for a cleaner and more sustainable future.
Storage enables electricity systems to remain in balance despite variations in wind and solar availability, allowing for cost-effective deep decarbonization while maintaining reliability. The
Calculating the nominal capacity required for wind farms, solar rooftops, and solar farms, along with the power and energy of energy storage, necessitates an accurate
Future research should focus on improving its hydrogen storage density and stability. In short, the future development of hydrogen energy technology requires breakthroughs in improving hydrogen storage density, reducing costs, and enhancing safety.
In short, hydrogen storage technology is a crucial bridge for hydrogen energy to move from the laboratory to practical large-scale applications. Its development level directly determines whether hydrogen energy can play a greater role in the future energy system.
Therefore, research and innovation in hydrogen storage technology are crucial for promoting the development of the hydrogen energy industry. By increasing hydrogen storage density, reducing costs, and improving safety, large-scale application of hydrogen energy can be achieved, thereby helping to achieve the “dual carbon” goal.
Although the current hydrogen energy storage technology has not yet reached the level of commercial application, its unique mechanism and potential advantages make it an essential direction for future research on hydrogen energy storage technology.
The development direction of hydrogen energy storage technology mainly focuses on improving hydrogen storage density, reducing energy consumption, and enhancing dehydrogenation efficiency to promote these technologies from laboratory to market applications.
From hydrogen production technology to storage and transportation technology to application technology, every technological advancement directly affects the economy and practicality of hydrogen energy. For example, the advancement of hydrogen production technology through the electrolysis of water improves hydrogen production efficiency.