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Van der Waals density functional studies of hydrogenated and lithiated bilayer graphene

In this thesis, we use rst principles density functional theory (DFT) to study the
energetics, structural and electronic properties of hydrogenated and lithiated bilayer
graphene material systems. The newly developed four variants of the non-local van der
Waals (vdW) exchange-correlation functionals (vdW-DF, vdW-DF2, vdW-DF C09x
and vdW-DF2 C09x) are employed to explore all the possible con gurations of hydrogen
adsorption at 50% and 100% coverage on a 1 1 unit cell. The results obtained are also
compared with the GGA PBE functional.
For 50% hydrogen coverage, 16 unique con gurations are identi ed in the unrelaxed
state. Formation energy analysis reveals six possible energetically favourable con gurations
with three low-energy competing con gurations. It is found that the properties
of hydrogenated bilayer graphene greatly depend on the hydrogen con guration. For
instance, the formation of a hydrogen dimer within the layers decouples the structure,
whereas the dimer formation outside surfaces does not have a signi cant in
uence on
the van der Waals forces; thus the bilayers remain coupled. In this coupled con guration,
the vdW-DF C09x functional predicts the lowest formation energy and shortest
interlayer separation, whereas the GGA PBE functional gives the highest formation
energy and largest interlayer distance. The reasons behind the variation of these functionals
are discussed. Two of the three low-energy competing con gurations exhibit
semimetallic behaviour, whereas the remaining con guration is a wide band gap material.
The wide band gap structure is found to undergo a hydrogen-induced spontaneous
phase transformation from hexagonal to tetrahedral (diamond-like) geometry. We conclude
that this wide band gap con guration represents a viable template for synthesizing
nanodiamonds from graphene by hydrogenation. At 100% coverage, ten unique
hydrogen con gurations are identi ed from a 1 1 unit cell. All exchange-correlation
functionals predict nine of the structures to have negative formation energies. From
these nine structures, three low-energy competing structures are noted and found to be wide band gap semiconductors, whereas the other con gurations exhibit either a
semimetallic or metallic character. Although a 1 1 unit-cell is able to present a clear
picture for the interaction between hydrogen and graphene, our results reveal that it
limits the occurrence of other interesting physics. The cell size was increased to 2 1, to
identify other low-energy con gurations that are not possible in a 1 1 cell. The identi
ed con gurations have shown physically interesting hydrogen arrangements such as
chair-like, zigzag-like and boat-like con gurations. Furthermore, our results reveal that
hydrogenation reduces the elastic properties of the pristine structures.
We further perform a systematic investigation of the e ects of lithium (Li) on AA
and AB stacking sequences of bilayer graphene. Two Li atoms are considered to examine
the e ects of the Li-Li interaction on bilayer graphene, and a total of 12 unique
con gurations for AB and 9 for AA stackings are identi ed. The vdW-DF consistently
predicts the highest formation energies, whereas vdW-DF2 C09x gives the lowest. Unlike
in the case of the pristine structures, it is noted that for lithiated bilayer graphene,
GGA PBE gives comparable results to the other functionals. One of the Li intercalated
con gurations undergoes a spontaneous translation from the AB to AA stacking,
and is found to be the most energetically stable con guration. We therefore conclude
that Li favours the AA stacking, and that con guration represents a feasible template
for experimentally synthesizing and characterizing a Li-based anode material. We noticed
that all identi ed Li con gurations exhibit metallic behaviour. Lastly, we found
that the intercalated Li dimer weakly interacts with the graphene layers, whereas the
intercalated isolated Li atom exhibits strong interaction. / Thesis (PhD)--University of Pretoria, 2014. / gm2014 / Physics / unrestricted

Identiferoai:union.ndltd.org:netd.ac.za/oai:union.ndltd.org:up/oai:repository.up.ac.za:2263/40220
Date January 2014
CreatorsMapasha, Refilwe Edwin
ContributorsChetty, Nithaya, edwin.mapasha@up.ac.za
Source SetsSouth African National ETD Portal
LanguageEnglish
Detected LanguageEnglish
TypeThesis
Rights© 2014 University of Pretoria. All rights reserved. The copyright in this work vests in the University of Pretoria. No part of this work may be reproduced or transmitted in any form or by any means, without the prior written permission of the University of Pretoria.

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