Silicon Nanostructures for Hydrogen Generation and Storage
Mussabek G. Yar-Mukhamedova G. Orazbayev S. Skryshevsky V. Lysenko V.
October 2025Multidisciplinary Digital Publishing Institute (MDPI)
Nanomaterials
2025#15Issue 19
Today, hydrogen is already widely regarded as up-and-coming source of energy. It is essential to meet energy needs while reducing environmental pollution, since it has a high energy capacity and does not emit carbon oxide when burned. However, for the widespread application of hydrogen energy, it is necessary to search new technical solutions for both its production and storage. A promising effective and cost-efficient method of hydrogen generation and storage can be the use of solid materials, including nanomaterials in which chemical or physical adsorption of hydrogen occurs. Focusing on the recommendations of the DOE, the search is underway for materials with high gravimetric capacity more than 6.5% wt% and in which sorption and release of hydrogen occurs at temperatures from −20 to +100 °C and normal pressure. This review aims to summarize research on hydrogen generation and storage using silicon nanostructures and silicon composites. Hydrogen generation has been observed in Si nanoparticles, porous Si, and Si nanowires. Regardless of their size and surface chemistry, the silicon nanocrystals interact with water/alcohol solutions, resulting in their complete oxidation, the hydrolysis of water, and the generation of hydrogen. In addition, porous Si nanostructures exhibit a large internal specific surface area covered by SiHx bonds. A key advantage of porous Si nanostructures is their ability to release molecular hydrogen through the thermal decomposition of SiHx groups or in interaction with water/alkali. The review also covers simulations and theoretical modeling of H2 generation and storage in silicon nanostructures. Using hydrogen with fuel cells could replace Li-ion batteries in drones and mobile gadgets as more efficient. Finally, some recent applications, including the potential use of Si-based agents as hydrogen sources to address issues associated with new approaches for antioxidative therapy. Hydrogen acts as a powerful antioxidant, specifically targeting harmful ROS such as hydroxyl radicals. Antioxidant therapy using hydrogen (often termed hydrogen medicine) has shown promise in alleviating the pathology of various diseases, including brain ischemia–reperfusion injury, Parkinson’s disease, and hepatitis.
hydrogen generation , hydrogen storage , porous silicon , silicon composites , silicon nanostructures
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National Nanotechnology Laboratory of Open Type, Al-Farabi Kazakh National University, Almaty, 050040, Kazakhstan
Institute of Information and Computational Technologies, Almaty, 050072, Kazakhstan
Educational Scientific Institute of High Technologies, Taras Shevchenko National University of Kyiv, Kyiv, 01601, Ukraine
Corporation Science Park, Taras Shevchenko University of Kyiv, Kyiv, 01033, Ukraine
Light Matter Institute, UMR-5306, Claude Bernard University of Lyon, CNRS, Université de Lyon, Villeurbanne Cedex, 69622, France
National Nanotechnology Laboratory of Open Type
Institute of Information and Computational Technologies
Educational Scientific Institute of High Technologies
Corporation Science Park
Light Matter Institute
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