The volumetric hydrogen storage capacity of 28 kg·m−3 achieved in our films is comparable to that of pressurized steel cylinders, highlighting their potential for practical applications. Our
Dielectric thin film capacitors are essential for miniaturized electronics and energy storage systems, offering ultrafast charge-discharge rates and high reliability.
Proton batteries are hydrogen storage devices that enable reversible electrochemical conversion of hydrogen energy into electrical energy. The history of proton
Plasma Kinetics hydrogen storage is a reversible solid-state which differs from compressed, liquid and metal hydride storage systems. Green plants use chlorophyll to store light energy in a
Here, we show that an α−MoO3 thin film, grown via atomic layer deposition, is a material with potential for reversibly storing hydrogen. We found that hydrogen plasma is a convenient way
The research aims to assess and progress hydrogen storage systems from 2010 to 2020 with an emphasis on obtaining high efficiency, safety, and capacity. To strengthen
1. Introduction As a very important functional material, hydrogen storage materials play an irreplaceable role in the field of secondary energy, especially in the research of fuel cells and
Achieving superior energy storage performance for all-organic PVDF/MG crosslinked composite dielectric films through the cooperation of crosslinking and hydrogen
Hydrogen is an energy vector capable of storing and supplying large amounts of energy, maximising the benefits of renewable and sustainable energy sources. Hydrogen is
Hydrogen energy has been assessed as a clean and renewable energy source for future energy demand. For harnessing hydrogen energy to its fullest poten
A storage technology with potential for different applications is hydrogen storage via absorption in metal hydrides. This technology offers high volumetric energy
The interaction of hydrogen with solids and the mechanisms of hydride formation experience significant changes in nanomaterials due to a
Mg–Y thin films capped with Pd have been prepared by direct current magnetron co-sputtering system. It is found that Mg alloyed with Y in film state forms ultrafine
This work highlights the energy storage capability of PIM-1 nanoparticulate films for local hydrogen storage at electrode surfaces. Further work following this project will
This work provides an overview of hydrogen economy as a green and sustainable energy system for the foreseeable future, hydrogen
Plasma Kinetics makes light-activated hydrides. It removed the hydrogen from a hydride using light. It system is safe, clean, and scalable and
In summary, bio-inspired scalelike PEI/BNNS films were prepared via hydrogen bond self-assembly process to synchronously improve their dielectric properties and
We built a thin film model to investigate their hydrogen absorption and desorption kinetics in ambient air, as well as chemical and electrical switching behaviors by analyzing
The extensive use of petroleum-based dielectric composites has caused many environmental problems, which has forced us to turn our attention to biodegradable materials.
The supercapacitor structure for energy storage requires a large specific surface area to achieve high performance. Engineering of the preparation and material properties of
Nanometer scale imaging of hydrogen in solid materials remains an important challenge for the characterization of advanced materials, such as semiconductors, high
Hydrogen and fuel cells are considered as key solutions for the 21st century, offering a clean and efficient production of power and heat especially without any negative
Hydrogen storage is one of the key enabling technologies for realization of hydrogen energy economy. Mg-based materials have been extensively studied as solid-state
Characteristics such as high hydrogen content, low energy consumption, economical and safety-conscious performance are desirable for hydrogen mobile storage.
Most available systems involving Zr in the literature are based on composite formation and utilize energy-intensive methods and equipment, limited information on the use
With the ever growing demand of energy, the focus is on alternative energy sources which are renewable and have less or no impact on climate. Among the many energy
These films were vacuum annealed at 573 K temperature for one hour to obtain homogeneous and intermixed structure of bilayer. Hydrogenation of these thin film structures
Here, we show that an α–MoO 3 thin film, grown via atomic layer deposition, is a material with potential for reversibly storing hydrogen. We
Mg and Mg-based thin film materials are believed appropriate options for hydrogen storage, and thermal energy storage due to their comparatively high reaction
This manuscript explores the diverse and evolving landscape of advanced ceramics in energy storage applications. With a focus on addressing the pressing demands of
