| Autore: |
Srinivasan Sesha
|
| Titolo: |
Clean Energy and Fuel (Hydrogen) Storage
|
| Pubblicazione: |
MDPI - Multidisciplinary Digital Publishing Institute, 2019 |
| Descrizione fisica: |
1 electronic resource (278 p.) |
| Soggetto non controllato: |
MgH2 |
| |
vertically oriented graphene |
| |
gas loss |
| |
concentrated solar power (CSP) |
| |
complex hydrides |
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PCM roof |
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hydrogen storage systems |
| |
slag |
| |
bubbles transportation |
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dye-sensitized solar cells |
| |
undercooling |
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methanogenesis |
| |
electrochemical energy storage |
| |
hydrogen storage |
| |
Fischer–Tropsch |
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state of charge estimator |
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gas turbine engine |
| |
simplified electrochemical model |
| |
hot summer and cold winter area |
| |
rock permeability |
| |
flutter instability |
| |
charge density |
| |
binder |
| |
salt cavern energy storage |
| |
battery energy storage system |
| |
capacitance |
| |
LiNH2 |
| |
ball milling |
| |
production rate |
| |
leaching tubing |
| |
quality function deployment (QFD) |
| |
nanocatalyst |
| |
lab-scale |
| |
thermal energy storage (TES) |
| |
comprehensive incremental benefit |
| |
lean direct injection |
| |
Li-ion batteries |
| |
separator |
| |
four-point |
| |
salt cavern |
| |
low emissions combustion |
| |
ionic liquid |
| |
carbon materials |
| |
nanocomposite materials |
| |
electrical double layers |
| |
recovery factor |
| |
thermochemical energy storage |
| |
Klinkenberg method |
| |
flow-induced vibration |
| |
cathode |
| |
porous media |
| |
metal hydride |
| |
aquifer size |
| |
diffusion |
| |
auxiliary services compensation |
| |
water invasion |
| |
conjugate phase change heat transfer |
| |
heat transfer enhancement |
| |
failure mode and effect analysis (FMEA) |
| |
magnetism |
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carbonate gas reservoirs |
| |
equivalent loss of cycle life |
| |
internal and reverse external axial flows |
| |
thermal energy storage |
| |
lithium-ion batteries |
| |
bacterial sulfate reduction |
| |
crystal growth rates |
| |
optimal capacity |
| |
gas storage |
| |
energy discharge |
| |
anode |
| |
Ag nanoparticles |
| |
regenerator |
| |
hydrogen absorption |
| |
freestanding TiO2 nanotube arrays |
| |
material science |
| |
extended kalman filter |
| |
reactive transport modeling |
| |
synthetic rock salt testing |
| |
hydrogen energy storage |
| |
lattice Boltzmann method |
| |
dynamic modeling |
| |
bubbles burst |
| |
Power to Liquid |
| |
large-scale wind farm |
| |
PHREEQC |
| Persona (resp. second.): |
StefanakosElias |
| Sommario/riassunto: |
Clean energy and fuel storage are often required for both stationary and automotive applications. Some of these clean energy and fuel storage technologies currently under extensive research and development include hydrogen storage, direct electric storage, mechanical energy storage, solar–thermal energy storage, electrochemical (batteries and supercapacitors), and thermochemical storage. The gravimetric and volumetric storage capacity, energy storage density, power output, operating temperature and pressure, cycle life, recyclability, and cost of clean energy or fuel storage are some of the factors that govern efficient energy and fuel storage technologies for potential deployment in energy harvesting (solar and wind farms) stations and onboard vehicular transportation. This Special Issue thus serves the need for promoting exploratory research and development on clean energy and fuel storage technologies while addressing their challenges to practical and sustainable infrastructures. |
| Altri titoli varianti: |
Clean Energy and Fuel |
| Titolo autorizzato: |
Clean Energy and Fuel (Hydrogen) Storage |
|
| ISBN: |
3-03921-631-7 |
| Formato: |
Materiale a stampa  |
| Livello bibliografico |
Monografia |
| Lingua di pubblicazione: |
Inglese |
| Record Nr.: | 9910367752503321 |
|
| Lo trovi qui: | Univ. Federico II |
| Opac: |
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