In the global quest to mitigate carbon emissions, hydrogen energy carriers (HECs) surface as a vital component of future energy systems. According to recent findings in the International Journal of Hydrogen Energy, ammonia (NH3) stands out among its peers with a specific energy consumption (SEC) of 7.67 kWh/kg of hydrogen.
With the global push towards carbon neutrality by 2050, hydrogen (H2) is increasingly positioned as a cornerstone of future energy…
Green hydrogen production is increasingly seen as the quintessence of clean energy systems. With the global pivot toward renewable energy,…
Solar and wind energies have long been at the forefront, renown for their environmental credentials and resource abundance. However, their…
A recent report by RenewableUK has thrust a crucial issue into the spotlight: the integration of energy storage and green hydrogen projects alongside offshore wind farms.
Energy storage systems (ESS) in smart grids represent a growing sector with profound potential. According to industry reports, the global energy storage market was valued at $11 billion in 2022 and is expected to surpass $58 billion by 2025.
When examining the burgeoning sector of ocean renewables, a noteworthy statistic emerges from the backdrop—global investment in marine renewable energy technologies surpassed $6 billion in 2023, reflecting a paradigm shift toward harnessing offshore resources.
According to recent studies, the efficient transportation of liquid hydrogen (LH2) presents formidable challenges, with up to 20% of the hydrogen potentially being lost via evaporation during transit.
Current data from the International Energy Agency indicates that buildings account for over a third of global energy consumption, with expected growth to 60% by 2050.
Research findings suggest that nanopores in certain minerals can significantly enhance hydrogen adsorption capacity due to stronger interactions with mineral surfaces.
