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The objective of this thesis is to investigate the hydrogen storage properties of
various metal decorated materials by using rst principles calculations based on density
functional theory (DFT). An increasing energy demand, and a limited supply of
fossil fuels, their adverse e ect on the environment require the need for a clean and
sustainable energy source. Hydrogen holds the promise to replace the widespread
dependency on fossil fuels due to its renewable, light weight, highly abundant, the
highest energy density per unit mass and produce water when used in fuel cells. High
gravimetric and volumetric storage densities, optimal thermodynamics, and fast reaction
kinetics are essential for an e ective hydrogen storage system. Thus the materials
based hydrogen storage with an emphasis on the necessary properties for reversible
hydrogen storage have been explored.
A variety of di erent materials such as graphene, carbon nanotubes, fullerenes,
graphynes, metal-organic frameworks and covalent organic frameworks reported for
hydrogen storage experimentally and theoretically but none of them have met the
ultimate target set by the US Department of Energy due to low e ciency in storage
and release of hydrogen at ambient temperature and pressure conditions.
DFT has been applied to explore the hydrogen storage properties of the systems by
using two di erent methods, i.e., global hybrid functional M06 and generalized gradient
approximation (GGA) based on the system size. The global hybrid functional M06
with 6-311G(d,p) basis set have been used to explore the hydrogen storage properties
of metal decorated calix[4]arene and its derivatives. However, the hydrogen storage
properties of metalorganic and inorganic frameworks have been studied by GGA with double numeric polarization (DNP) basis set. The structural, thermochemical,
and electronic properties have been studied.
The hydrogen storage properties of light metals such as Li, Sc, and Ti decorated
calix[4]arene and its derivatives have been explored. The hydrogen sorption properties
of metal decorated metal-organic frameworks viz.; metal-graphyne framework
(MGF), metal-carbyne framework (MCF) and metal inorganic framework made up
of inorganic borazocine linker (MBF) have been studied. Metal atoms bind with CX
systems, MGF, MCF, and MBF by Dewar coordination. The hydrogen molecules are
adsorbed on the open metal sites of metal decorated systems by Kubas-Niu-Rao-Jena
mechanism. It was observed that 3 to 6 H2 molecules adsorbed on per metal atom
in the metal decorated system. The average hydrogen adsorption and sequential desorption
energies are calculated and found in the required range for metal decorated
CX, MGF, and MBF systems. The charge transfer mechanism during the hydrogen
adsorption is studied by Hirshfeld charge analysis and electrostatic potential maps.
The reversibility of adsorbed hydrogen and the stability of the metal decorated systems
is studied by Born-Oppenheimer molecular dynamics simulations. Based on rst
principles calculations, the hydrogen storage properties of di erent metal decorated
materials have been explored, which can be considered as potential hydrogen storage
materials.
A summary of the present work is given at the end of the thesis along with the
conclusions and the future direction of research followed by a bibliography. |
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