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Nanoconfined Alkali-metal borohydrides for Reversible Hydrogen Storage
P. Ngene
Sub Inorganic Chemistry and Catalysis
Research output
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Thesis
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Doctoral thesis 1 (Research UU / Graduation UU)
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Keyphrases
Nanoconfined
100%
Alkali Metals
100%
Hydrogen Release
100%
Reversible Hydrogen Storage
100%
Metal Borides
100%
Nanoconfinement
85%
LiBH4
57%
NaBH4
42%
Nanoporous Carbon Materials
42%
Complex Metal Hydrides
28%
Nanosize
28%
Hydrogen Uptake
28%
Nanoporous
28%
Physical Confinement
28%
Ni Nanoparticles
28%
Pollution
14%
Renewable Energy
14%
Thermodynamics
14%
Mass Transport
14%
Energy Carrier
14%
Ordered Mesoporous Silica
14%
Non-associated
14%
Transport Distance
14%
Energy Storage
14%
Elevated Temperature
14%
Host Material
14%
Dehydrogenation
14%
Silicate
14%
Effective Strategies
14%
Scale Usage
14%
Combustion
14%
Onboard Hydrogen Storage
14%
Hydrogen Sorption Properties
14%
Gravimetric Method
14%
Hydrogen Content
14%
Sustainable Energy Systems
14%
Alkali
14%
High Purity
14%
Decomposition Temperature
14%
Support Effect
14%
Reduced Mass
14%
Release Kinetics
14%
Uptake Kinetics
14%
Carbon Materials
14%
Release Temperature
14%
Decomposition Pathway
14%
Nanostructured Scaffolds
14%
Mesoporous Silica SBA-15
14%
Mesoporous Silica
14%
Rate Stability
14%
Borohydride
14%
Porous Carbon Materials
14%
Reversible Capacity
14%
Intermittent Energy
14%
Metal Hydride
14%
New Preparations
14%
Hydrogen Density
14%
Material Science
Alkali Metal
100%
Metal Hydride
60%
Nanoparticle
40%
Nanocomposite
40%
Porous Carbon
20%
Density
20%
Silicate
20%
Dehydrogenation
20%
Ordered Mesoporous Silica
20%
Mesoporous Silica
20%