INIS
quantum dots
100%
thermodynamics
100%
sorption
100%
interfaces
100%
size
100%
strains
100%
hydrogen
33%
hydrides
33%
membranes
22%
energy
22%
aluminium oxides
22%
absorption
22%
desorption
22%
field emission
11%
surfaces
11%
substrates
11%
low temperature
11%
morphology
11%
scanning electron microscopy
11%
masks
11%
decomposition
11%
molecular beam epitaxy
11%
hysteresis
11%
layers
11%
glass
11%
comparative evaluations
11%
isotherms
11%
magnesium oxides
11%
evaporation
11%
plasticity
11%
engineering
11%
atomic force microscopy
11%
high pressure
11%
porosity
11%
Chemical Engineering
Thermodynamics
100%
Sorption
100%
Hydride
100%
Hydrogen
100%
Alumina
66%
Desorption
66%
Molecular Beam Epitaxy
33%
Temperature
33%
Keyphrases
Nanodots
100%
Sorption Thermodynamics
100%
Strain Effect
100%
Ultra-thin Alumina Membrane
22%
Plateau Pressure
22%
Hydride Formation
22%
Hydrogenography
11%
Hydrogen Sorption
11%
Molecular Beam Epitaxy
11%
Elastic Strain Energy
11%
Interface Energy
11%
Lateral Surface
11%
Elastic Strain Engineering
11%
Ordered Porosity
11%
Upward Shift
11%
Hydride Decomposition
11%
Nanoconfined
11%
Pressure Hysteresis
11%
Coated Glass
11%
Material Science
Nanodots
100%
Hydride
33%
Membrane
22%
Desorption
22%
Aluminum Oxide
22%
Microscopy
11%
Temperature
11%
Molecular Beam Epitaxy
11%
Porosity
11%
Glass
11%
Morphology
11%
Plastic Deformation
11%
Surface
11%
Field Emission Scanning Electron Microscopy
11%
Engineering
Nanodots
100%
Nanopatterning
11%