Power-to-X (PtX) will play a pivotal role in decarbonizing gas-based industries by enabling the conversion of renewable electricity into various forms of energy carriers such as hydrogen and synthetic fuels. By integrating gas hydrates as a storage medium, PtX can effectively link renewable energy sources with the gas-based industry, facilitating a smoother transition toward a low-carbon economy. Hydrogen (H 2 ) storage is a pressing issue due to its low density and the high costs of compression and liquefaction. This study explores the potential of gas hydrate technology for large-scale H 2 storage, particularly in blends with natural gas (H 2 −NG). The research delves into the thermodynamic and kinetic properties of H 2 −NG hydrates, demonstrating that gas hydrates could offer a viable alternative to traditional storage methods. Experimental and simulation studies indicate that the inclusion of gaseous promoters like methane (CH 4 ) and propane (C 3 H 8 ) can enhance the H 2 storage capacity within hydrates. The study outlines the formation conditions and stability of various hydrate structures, emphasizing the role of promoters in facilitating H 2 enclathration. Importantly, the study highlights the practical and feasible pathway for the energy transition by integrating H 2 storage into the natural gas infrastructure. The economic analysis underscores the cost-effectiveness of hydrate-based storage compared to conventional methods, considering factors such as energy efficiency and capital expenditure. This study proposes a detailed process for forming, storing, and transporting H 2 −NG hydrate pellets, highlighting the potential for integrating this method into existing natural gas infrastructures. The findings suggest that, with further optimization, gas hydrate technology could play a crucial role in the H 2 economy, offering an efficient and sustainable solution for H 2 storage, thus supporting global efforts toward carbon neutrality and clean energy adoption.
