Hydrogen Production, Purification, Storage, Transportation, and Their Applications: A Review

Panda, P. K.; Sahoo, Bijaylaxmi; Ramakrishna, Seeram

doi:10.1002/ente.202201434

Cited by 13 publications

(4 citation statements)

References 117 publications

(139 reference statements)

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“…The global energy crisis caused by increasing energy consumption calls for sustainable alternative energy sources. Although H 2 is the most promising energy source with high energy density and CO 2 -free emissions, more than 90% of H 2 is produced by the steam reforming process of natural gas using fossil fuel hydrocarbons, which emit CO 2 [73]. The produced H 2 is expected to be used as energy in fuel cell vehicles (FCVs), FC buses, and power generation; however, to date it has been used in large-scale processes in various industries, including petrochemicals, electronics, metallurgy, steelmaking, pharmaceuticals, and the production of raw material chemicals.…”

Section: Co2 Capture and H2 Purificationmentioning

confidence: 99%

Recent Progress and Challenges in the Field of Metal–Organic Framework-Based Membranes for Gas Separation

Tanaka,

Fuku,

Ikenaga

et al. 2024

Compounds

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Metal–organic frameworks (MOFs) represent the largest class of materials among crystalline porous materials ever developed, and have attracted attention as core materials for separation technology. Their extremely uniform pore aperture and nearly unlimited structural and chemical characteristics have attracted great interest and promise for applying MOFs to adsorptive and membrane-based separations. This paper reviews the recent research into and development of MOF membranes for gas separation. Strategies for polycrystalline membranes and mixed-matrix membranes are discussed, with a focus on separation systems involving hydrocarbon separation, CO2 capture, and H2 purification. Challenges to and opportunities for the industrial deployment of MOF membranes are also discussed, providing guidance for the design and fabrication of future high-performance membranes. The contributions of the underlying mechanism to separation performance and adopted strategies and membrane-processing technologies for breaking the selectivity/permeability trade-off are discussed.

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Section: Co2 Capture and H2 Purificationmentioning

confidence: 99%

Recent Progress and Challenges in the Field of Metal–Organic Framework-Based Membranes for Gas Separation

Tanaka,

Fuku,

Ikenaga

et al. 2024

Compounds

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“…Additionally, another study focused on improving the efficiency and performance of refueling stations for Hydrogen [19]. Notably, one study achieved a cumulative hydrogen production rate surpassing the maximum reported for pure TiO2-based photocatalysts [20]. However, it's worth considering that solar energy may face limitations in meeting production requirements due to its availability primarily during the daytime, challenges related to shadows, and temperature variations.…”

Section: Hydrogen Generation From Solar Energymentioning

confidence: 99%

Hydrogen Production and Applications: A review

Marghani,

Chater,

Bouganssa

et al. 2023

E3S Web of Conf.

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A hydrogen fuel cell car, known as a Fuel Cell Electric Vehicle (FCEV), is essentially an electric vehicle that primarily relies on a fuel cell to generate energy. It also includes a secondary role for a battery within the powertrain. This technological configuration operates through four main scenarios, with the primary energy source being Hydrogen from onboard tanks, which powers the vehicle through the fuel cell and its associated components. Here's a breakdown of how it functions: Hydrogen enters the anode and interacts with a catalyst that separates hydrogen atoms, releasing electrons and protons. A conductive current collector connected to the vehicle's high-voltage circuitry collects these electrons. This electricity can charge the battery and/or drive the motors responsible for propelling the wheels. Fuel cells come in various types, characterized by the type of electrolyte they use, such as the Proton Exchange Membrane Fuel Cell (PEMFC), Solid Oxide Fuel Cell (SOFC), and Molten Carbonate Fuel Cell (MCFC). While all these fuel cell types can generate electricity, their efficiency can range from 30% to 60%. Although hydrogen fuel cell vehicles have shown promise, their adoption is still in its early stages due to challenges related to infrastructure, costs, and ongoing technological advancements. Our current research focuses on hydrogen production from renewable sources and its application in fuel cells to provide the required electrical power for electric vehicle propulsion. We aim to improve energy efficiency over a specified cycle and present a comprehensive analysis of our findings.

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“…1,2 However, H 2 is highly compressible, explosive, and volatile, posting challenges for large-scale surface storage techniques. 3,4 Alternatively, subsurface formations, e.g., salt deposits, aquifers, and depleted hydrocarbon reservoirs, show great promise for large-scale hydrogen storage. 5−7 The wettability of the porous formations is vital in ensuring storage safety, efficiency, and capacity.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Hydrogen (H 2 ) is a clean and promising energy carrier to balance the mismatch between renewable energy demand and supply. , However, H 2 is highly compressible, explosive, and volatile, posting challenges for large-scale surface storage techniques. , Alternatively, subsurface formations, e.g., salt deposits, aquifers, and depleted hydrocarbon reservoirs, show great promise for large-scale hydrogen storage. − The wettability of the porous formations is vital in ensuring storage safety, efficiency, and capacity. For instance, the wettability of sediment rocks is decisive in fluid transport behavior and fluid distribution.…”

Section: Introductionmentioning

confidence: 99%

Molecular Insights into the Impact of Surface Chemistry and Pressure on Quartz Wettability: Resolving Discrepancies for Hydrogen Geo-storage

Zheng,

Germann,

Gross

et al. 2024

ACS Sustainable Chem. Eng.

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Subsurface formations are promising for large-scale H 2 storage, balancing the energy demand and supply. Wettability is vital in ensuring storage safety, efficiency, and capacity, whereas noticeable discrepancies exist in the literature. This work reconciles these discrepancies by revealing the mechanisms of quartz wettability alteration with surface chemistry and pressure using classical molecular dynamics simulation. We find that the fully rigid quartz substrate results in much lower hydrophilicity than the fully flexible and the hydroxyl group flexible quartz substrates due to the lower probability of hydrogen bond formation between water and hydroxyl groups. Also, quartz wettability relies on not only the area density but also the arrangement of the surface hydroxyl groups. Monolayer water adsorption on both hydrophilic and hydrophobic quartz surfaces is observed, whereas the structure of the adsorbed water film is different. Dissolved H 2 prefers to move to the quartz surface rather than staying in bulk water. The water contact angle on the fully hydroxylated quartz fluctuates between 30.7 and 37.1°with pressure ranging from 1− 30 MPa, without a monotonic trend. We reveal that the dominant mechanism of wettability alteration within this pressure range is due to the pinning effect induced by the microstructures on the quartz surface.

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Hydrogen Production, Purification, Storage, Transportation, and Their Applications: A Review

Cited by 13 publications

References 117 publications

Recent Progress and Challenges in the Field of Metal–Organic Framework-Based Membranes for Gas Separation

Recent Progress and Challenges in the Field of Metal–Organic Framework-Based Membranes for Gas Separation

Hydrogen Production and Applications: A review

Molecular Insights into the Impact of Surface Chemistry and Pressure on Quartz Wettability: Resolving Discrepancies for Hydrogen Geo-storage

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