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Tunable Electronic Properties of ChemicallyFunctionalized Graphene and Atomic-ScaleCatalyticsKelvin L. SuggsClark Atlanta University, [email protected]
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Tunable Electronic Properties of Chemically Functionalized Graphene and Atomic-Scale Metallic Catalytics
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TUNABLE ELECTRONIC PROPERTIES OF CHEMICALLY FUNCTIONALIZED
GRAPHENE AND ATOMIC-SCALE METALLIC CATALYTICS
A DISSERTATION
SUBMITTED TO THE FACULTY OF CLARK ATLANTA UNIVERSITY
IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR
THE DEGREE DOCTOR OF SCIENCE
BY
KELVIN L. SUGGS
DEPARTMENT OF CHEMISTRY
ATLANTA, GEORGIA
JULY 2015
© 2015
KELVIN L. SUGGS
All Rights Reserved
ABSTRACT
DEPARTMENT OF CHEMISTRY SUGGS, KELVIN L. B.S. MOREHOUSE COLLEGE, 2000
M.S. CLARK ATLANTA UNIVERSITY, 2010
TUNABLE ELECTRONIC PROPERTIES OF CHEMICALLY FUNCTIONALIZED GRAPHENE AND ATOMIC-SCALE METALLIC
CATALYTICS
Committee Chair: Xiao-Qian Wang, Ph.D. Dissertation dated July 2015
In this dissertation, we discuss the electronic properties, structural
configurations, and reaction mechanisms of chemically functionalized graphene and
charged atomic metals. In general, we analyze fundamental atomic scale and
nanoscale systems with density functional theory in order to investigate chemical
reaction energetics for peroxide synthesis as well as methanol production without
carbon emission. These systems were found to be tunable via the addition of cationic
and anionic charges, change in transition metal type, and modification through
chemical functionalization. Furthermore, transition state theory was used to predict an
optimal configuration for chemically functionalized graphene, efficient use of anionic
atomic gold and palladium for synthesis of water to peroxide, and clean conversion of
methane to methanol without carbon dioxide emission utilizing anionic gold.
ii
ACKNOWLEDGMENTS
I am greatly indebted to my parents, Ernest and Arbedella Suggs, for their
inspiring presence. Moreover, I extend great appreciation to my brothers, Tirrell and
Michael Suggs, for motivating me to endeavor in the realm science. I further gratitude
to Mr. and Mrs. Fred L. Suggs, Mr. and Mrs. Roland Suggs, Morris and Mary
Williams, Drs. Ernestine and Albert Suggs, Bryant and Loretta Suggs, Mariya
Dickens, E.S. and Doris Suggs, Denmark Suggs. I thank my colleagues Dr. Olayinka
Ogunro, Cherno Baba Kah, Dr. Duminda K. Samarakoon, Rosi N. Gunasinghe, Dr.
Darkeyah Reuvan, Dr. Zineb Felfli, Dr. Praphat Xavier Fernandes, Joyce Lockhart,
Debra Heard, and Ms. Ware for their invaluable advice and support. Finally, I extend
gratitude to Ana Maria Jauregui, Maria “Esther” del Cacho Suggs, Jose Antonio del
Cacho and family, and Maria Carmen del Cacho. I extend gratitude to Grandparents
Lucille Belcher, James Earl Jones, Eddie and Minnie Jones, Fred and Hattie Suggs,
and the Lee family and for their support and humor. A special thank you goes to Drs.
Xiao-Qian Wang and Alfred Msezane for their steadfast support throughout my
matriculation. I further appreciate financial support from the NSF (Grant No. DMR-
0934142), Title III, the Center for Functional Nanoscale Materials (CFNM) at Clark
Atlanta University, and the PRISM (Problems and Research to Integrate Science and
Mathematics) program under the auspices of Dr. P. Marsteller at Emory University.
iii
TABLE OF CONTENTS
ACKNOWLEDGEMENTS ................................................................................. ii
LIST OF FIGURES ................................................................................................................ vi
LIST OF TABLES ............................................................................................... viii
LIST OF ABBREVIATIONS ............................................................................. ix CHAPTER 1 INTRODUCTION ........................................................................ 1
1.1 Overview of Chemically Functionalized Graphene ............... 2
1.2 Methods and Calculations ...................................................... 5
1.3 Results and Discussions ......................................................... 7
1.4 Closing Remarks .................................................................... 14
1.5 Conclusions ............................................................................ 16
2 SELF-ASSEMBLY OF BIOFUNCTIONAL POLYMER ON GRAPHENE NANORIBBONS ................................................... 18
2.1 Introduction ............................................................................ 18 2.2 Results and Discussions ......................................................... 19
2.3 Methods .................................................................................. 30
2.4 Conclusions ............................................................................ 31 3 THEORETICAL INVESTIGATION OF PEROXIDE SYN-
THESIS USING ATOMIC NEGATIVE IONS ........................... 32
3.1 Introduction ........................................................................... 32
3.2 Theoretical overview ............................................................. 35
3.3 Reaction Dynamics ................................................................ 37
iv
3.4 Thermodynamics of Reactions .............................................. 38
3.5 Calculations Utilizing CAM theory, and Transition State
Theory .................................................................................... 39
3.6 Rate of Reaction Calculation ................................................. 42
3.7 Results and Data .................................................................... 42
3.8 Discussions ............................................................................ 50
3.8.1 The Atomic Physics Analysis ....................................... 50
3.8.2 Thermodynamics Calculation ....................................... 51
3.8.3 Hydrogen Bonding Calculation .................................... 54
3.8.4 Rate of Reaction Calculation ........................................ 54
3.8.5 Relativistic Effects ........................................................ 56
3.9 Summary and Conclusion ...................................................... 57 4 GOLD ANION CATALYSIS OF METHANE TO METHANOL
WITHOUT CO2 EMISSION ........................................................ 59
4.1 Introduction ............................................................................ 59
4.2 Reaction and Calculation Method .......................................... 62
4.3 Results and Discussion ........................................................... 65
4.4 Understanding the Results ...................................................... 69
4.5 Resonance Scattering Approach ............................................. 71
4.6 Thermodynamics of Reactions ............................................... 73
4.7 Transition-State Calculations ................................................ 74
4.8 Remarks on the Results ......................................................... 77
4.9 Discussion of Results ............................................................ 78
v
4.10 Conclusions .......................................................................... 80 REFERENCES ..................................................................................................... 81
vi
LIST OF FIGURES
Figure 1. Top view of the molecular structures of perfluorphenylazide (PFPA). 5
Figure 2. Calculated transition-state (TS) structure between the non-interacting
PFPA/graphene .................................................................................... 9
Figure 3. Ball-and-stick representation of optimized PFPA/graphene ............... 11
Figure 4. Calculated band structures for pristine graphene ................................ 12
Figure 5. Isosurface plot of charge densities of the hybridized valence ............ 14
Figure 6. Calculated band structures for (a) PFPA-functionalized graphene ..... 16
Figure 7. m-P2MS chemical scheme and optimized geometry .......................... 21
Figure 8. Supramolecular organization of polymer features on GNR ................ 23
Figure 9. m-P2MS polymer ordering on GNR and IgE binding ........................ 27
Figure 10. Multi-micron polymer ordering on GNR ............................................ 29
Figure 11. Catalytic cycle of the oxidation of heavy water to heavy peroxide .... 37
Figure 12. Electron Affinity calculations ............................................................. 44
Figure 13. Optimized structures of (a) intermediate water (HDO) ...................... 48
vii
Figure 14. Optimized structures of (a) heavy water oxidation ........................... 49
Figure 15. Change in entropy, ∆S (cal/mol•K), vs temperature, T (K) .............. 53
Figure 16. Complete oxidation of methane to carbon dioxide and water .......... 66
Figure 17. Oxidation of methane to carbon monoxide and hydrogen gas .......... 66
Figure 18. Oxidation of methane to methanol .................................................... 67
Figure 19. Oxidation of methane to formaldehyde and water ............................ 67
Figure 20. Oxidation of methane to formic acid and hydrogen gas ................... 68
Figure 21. Change in the Gibbs free energy ....................................................... 71
viii
LIST OF TABLES
Table 1. Calculated electron affinities (EAs) and R–T minima ......................... 45
Table 2. TS and EP represent, respectively, the calculated transition state and
energy ................................................................................................... 47
Table 3. Calculated energy barrier, (EB), and hydrogen bonding, (HB), in eV. 54
Table 4. TS, EP, and T represent, respectively, the calculated transition state,
energy of the products and temperature of the reaction ....................... 68
ix
LIST OF ABBREVIATIONS
AFM Atomic Force Microscopy
BE Binding Energy
CAM Complex Angular Momentum
CB Charge Band
CBM Charge Band Minimum
COSMO Conductor-like Screening Model
DCACPs Dispersion-Corrected Atom-Centered Potentials
EA Electron Affinities
D Deuterium
DFT Dispersion-Corrected Density Functional Theory
DLS Dynamic Light Scattering
DNP Double Numerical Approximation
EP Energy of Product
GGA Generalized Gradient Approximation
GNRs Graphene Nanoribbons
H Enthalpy
HeLa Henrietta Lax cells
HOMO Highest Occupied Molecular Orbital
x
IgE Immunoglobulen E
LST Linear Synchronous Transit
LUMO Lowest Unoccupied Molecular Orbital
MWCNTs Multi-Walled Carbon Nanotubes
P2MS Poly-2 methoxy-styrene
PBE Perdew-Burke-Ernzerhof
PBS Phosphate Buffer solution
PEO Poly-ethylene oxide
PFPA Pefluorphenylazide
QST Quadratic Synchronous Transit
R-T Ramsauer-Townsend
S Entropy
SPO Selective Partial Oxidation
T Tritium
TCSs Total Cross Sections
THF TetraHydrofuran
TS Transition state
T-S Tkatchenko–Scheffler
VB Valence Band
VBM Valence Band Maximum
VDE Vertical Detachment Energy
1
CHAPTER 1
INTRODUCTION
In this dissertation, graphene functionalized by perfluorazide (PFPA) and
helical poly 2-methoxystyrene (m-P2MS), and the utilization of anionic metallic
atomic systems as catalysts are studied utilizing density functional theory.
Furthermore, we predict novel graphene-based functional molecules, and gain insight
into the catalytic mechanism in the oxidation of water to peroxide and methane to
methanol. Our calculations are contrasted with those from other theoretical models.
Chapters 1 and 2 investigate graphene-based structures that have been chemically
functionalized. Chapters 3 and 4 explore anionic atomic Au, Ag, and Pd metals for
use as effective catalysts for the oxidation of water to peroxide, and methane to
methanol to without CO2 emission. Moreover, we have performed calculations at the
atomic level and nanoscale that predict plausible applications in nanotechnology,
industrial catalysis, and green energy fields. By probing at the atomic-scale further
insight can be obtained into the larger scale systems that include bulk metals as well as
large-scale allotropic carbon. Various properties are calculated in this dissertation
including transition states, thermodynamics, bandstructures, and molecular
geometries. In general, this dissertation concludes that the tunability of a given
system, depending on its scale, can be achieved electronically, structurally, and via
chemical functionalization.
2
1.1 Overview of Chemically Functionalized Graphene
Graphene is a one-layer sheet of carbon atoms arranged in a honeycomb
lattice. It has attracted a great deal of attention due to its remarkable properties and
promising potential applications.1-5 These applications include transistors, integrated
circuits, and biosensors. Moreover, future development of these applications requires
an improved understanding of how to control the associated structural and electronic
properties. Because of the gapless character of the graphene band structure, the future
of graphene electronics depends on developing effective methods for band gap
engineering. A gap can be formed in epitaxial graphene grown on a lattice matched
substrate.6,7 Although the approach involving lattice matched substrates is
straightforward, combining it with electronic transport remains a challenging task.
Another promising method for gap engineering relies on spatial confinement,
such as patterning graphene into nanoribbons.8, 9 The gap obtained by such a method
can be tuned by varying the spatial width of graphene ribbons. However, the
approaches relying on spatial confinement are prone to rough edges and defects.
Moreover, although graphene nanoribbon field-effect transistors have been shown to
exhibit excellent properties,8,10 mass production of graphene nanoribbon-based devices
is beyond the capability of current lithography technology.6
Recently, there has also been a number of studies on generating a band gap in
the gapless bilayer graphene with a perpendicularly applied electric field.11-14 In
bilayer graphene, the Bernal stacking can be lifted by asymmetric chemical doping or
3
electrical gating,4 leading to a gap opening. On the other hand, a wealth of approaches
has been developed for noncovalently and covalently functionalized graphene.10,15-23
Graphene contains a paucity of functional moieties and limited dispersibility in
solvents, seriously hindering the realization of its great potential.16, 21-23 As a result,
developing chemical methods in order to tune the materials properties has become one
of the most critical issues in exploring graphene technologies. Various chemical
modification techniques have been shown to not only enhance its solubility and
processability but also produce suitable properties for graphene-based nanoelectronic
and nanophotonic devices. Modification of graphene's electronic properties has been
carried out by well-established chemical functionalization techniques, in wherein
groups, such as H, OH, or F, bind covalently to carbon atoms, transforming the
trigonal sp2 orbital to the tetragonal sp3 state.15,24-28 Such transformations drastically
modify the local electronic properties.
Recent experimental studies have demonstrated an efficient method to
covalently functionalize pristine graphene with the use of nitrene chemistry, in which
a perfluorophenylazide (PFPA) undergoes cycloaddition with C-C double bonds,
forming an aziridine-ring linkage (see Figure 1).23 A wide range of aryl azide
derivatives are available and can be further functionalized with an array of polymeric
functional groups. The aziridino-ring reaction can be carried out by thermal and
photochemical activation, which results in graphene being soluble in organic solvents
and water. The advancement of graphene-aryl-aziridine adduct nanocomposites
4
brings with it the need to understand their impact on the electrical properties of
graphene. In lieu of the increasing amount of experimental and theoretical studies of
chemically functionalized graphene, a better understanding of how covalent
functionalization impacts the morphology and electron/hole transport in graphene
becomes pivotal for its future application in nanoelectronics. Experimental advances
have motivated our study of the electronic structure characteristics of PFPA
functionalized graphene. Herein, we report on comprehensive results based on first-
principles density functional theory calculations. PFPA functionalized graphene
perturbs the π conjugation of graphene, and the corresponding electronic properties
change from metallic to semiconducting. We show that, with the increase of aziridine
adducts, the resultant energy gap can be tuned. Our work thus asserts the unique
opportunity of tailoring the band gap of graphene with varying chemisorption
compositions.
5
Figure 1. Top view of the molecular structures of perfluorphenylazide (PFPA)-functionalized graphene with PFPA carrying alkyl, ethylene oxide and perfluoroalyl groups. Carbon, fluorine, nitrogen, oxygen, and hydrogen atoms are colored in gray (green for graphene), light blue, blue, red, and white, respectively.
6
1.2 Methods of Calculations
The structural and electronic properties PFPA functionalized graphene were in
vestigated using first-principles density functional theory calculations as implemented
in the DMol3 package.36 The Perdew-Burke-Erzernhof (PBE) parametrization37 of the
generalized gradient approximation (GGA), with a supercell of a vacuum space of 16
Å normal to the graphene plane was used. A kinetic energy change of 3x10-4 eV in the
orbital basis and appropriate Monchorst-Pack k-point grids of 6 x 6 x 1 were sufficient
to converge the integration of the charge density. The optimization of atomic positions
proceeds until the change in energy was less than 1 x 10-6 eV per cell. Although the
GGA approach systematically underestimates the band gaps, we are primarily
interested in the mechanism of gap opening. The GGA approach is expected to
provide qualitatively correct information and remains the popular choice for
investigations of covalent functionalizations.14
To investigate the effect of addend concentration on the electronic structures,
we have considered two configurations by adding one or two PFPA polymers onto a 7
x 7 rhombus cell. The cell constitutes 98 carbon atoms for graphene, 7 carbon, 4
fluorine, 1 nitrogen, and 3 hydrogen atoms for each PFPA molecule. A transition-state
search employing a combination of LST/QST algorithms36 facilitates the evaluation of
energy barriers. For transition-state calculations, we used a graphene flake to model
the graphene layer and found that the distortion generated in the transition-state search
is not crucial for the extracted energy barrier (error less than 0.2 eV).
7
1.3 Results and Discussions
Covalent functionalization of graphene with polymers is advantageous in that
long polymer chains facilitate solubilizing graphene into a wide range of solvents,
even at a low degree of functionalization.16,21-23 Soluble graphene can further undergo
in situ polymerizations with the immobilized functional groups. Although important
for solubility, the side chains of PFPA are not crucial to the electronic properties of
this nano- composite.29 As such, we replaced the side chains of PFPA with methyl (-
CH3) groups in order to simplify the electronic structure calculations. One of the
important chemical reactions is the [2+1] cycloaddition of nitrenes, which has been
successfully used to functionalize carbon nanomaterials with high efficiency. Shown
in Figure 2 is the transition path along with the relative energies of the corresponding
[2+1] cycloaddition reaction for PFPA functionalized graphene.
The reactant constitutes the non-interacting PFPA and graphene, whereas the
product is the PFPA functionalized graphene in which the addition of a PFPA
saturates a double bond between two graphene carbon atoms, forming a cyclopropane-
like three-membered ring. Although the energy differences between the starting and
ending configurations is fairly small (about 0.1 eV), the transition barrier is 1.92 eV, in
good agreement with the experimental estimate of ∼2-3 eV.23 As the predominant
contribution to the transition barrier is attributed to the breaking of a N-N double bond
and the associated loss of N2, our results are in conformity with the experimental
observation that functionalization occurs on the surface of graphene after the [2+1]
8
cycloaddition of PFPA. We illustrate in Figure 3 the optimized conformation of PFPA
functionalized graphene. The PFPA molecule increases the bond lengths linking to
atoms on graphene. The corresponding bond length between the C atom on graphene
and the N atom of the PFPA molecule is around 1.43 Å, whereas that of the C atom
and its nearest neighbors on graphene is around 2.21 Å. The latter C-C distance is
notably larger than the C-C bond length of 1.42 Å of graphene with sp2 hybridization
and indicates bond breaking.
The C-C bond lengths in graphene beyond the nearest neighbors are found to
be little affected by the functionalization. The graphene-PFPA molecule interaction in
the covalent functionalization has direct consequences on the electronic properties of
graphene. Previous theoretical work investigated the addition of functional groups as
free radicals to graphene.24,25,29 These functional groups drastically disrupt the
geometries and electronic structures of graphene by introducing local sp3 hybridization
defects, which induce an sp3-type “impurity” state near the Fermi level.14,30,31 In the
cases of divalent functionalization, two sp3 states induced by two neighboring
functional sites are shifted away from the Fermi level due to the rehybridization into
bonding and anti-bonding states.31 Therefore, the local bonding configuration can
significantly affect the electronic structure of functionalized graphene.
9
Figure 2. Calculated transition-state (TS) structure between the noninteracting PFPA/graphene and the PFPA functionalized graphene plus a N2 molecule. PFPA adsorbs onto the graphene surface via a nitrene radical. After losing N2, PFPA reacts with graphene via an electrophilic [2 + 1] cycloaddition reaction. Carbon, fluorine, nitrogen, and hydrogen are colored in gray (green on graphene), light blue, blue, and white, respectively.
To further pursue this point, it is instructive to recall that, for nitrene
functionalized carbon nanotubes, the cyclopropane ring structure introduced by [2+1]
cycloadditions can either remain intact or lead to cleavage of the sidewall bonds with
the increase of the nanotube curvature, resulting in two valence tautomeric forms that
display distinct electronic characteristics and markedly different transport properties in
metallic tubes.30 In those cases, the nitrene chemistry introduces cyclopropane
10
functionality in place of the partial double bonds initially present in the π-conjugated
electronic structure. Each addition saturates a conjugated bond and causes the valence
of a pair of carbon atoms to revert from sp3 to sp2 hybridization.30,31
We depict in Figure 4 the calculated band structures for PFPA functionalized
graphene, along with the pristine graphene for comparison. It is readily observed that,
after the covalent functionalization, the π and π* linear dispersion of pristine graphene
in the proximity largely preserves the Dirac point (K). Therefore, a gap is created
between the π and π* states. These electronic properties of PFPA-functionalized
products are in sharp contrast to the sp3 rehybridization and loss of π electrons found
upon the addition of monovalent chemical groups in other functionalization
schemes.14,31 The absence of sp3-type “impurity” states in the vicinity of the Dirac
point is also consistent with the rationale that the C-C bond between the two
bridgehead atoms is either broken or substantially weakened, leading to partial
recovery of the π-electron system.
On the other hand, our present results are clearly distinct from those of the
noncovalent functionalization.14,32,33 For noncovalent functionalization, there is little
modification of the band structures close to the Fermi level, and the corresponding
bandstructure constitutes flat and dispersed bands that can be readily classified as
arising from functional group and pristine graphene contributions.34 By contrast, the
PFPA-functionalized graphene displays profound level hybridizations. In particular,
the bandgap opening at the Dirac point implies important perturbations generated by
11
the functionalization. All of the band gaps of the PFPA functionalized graphene
appear at the Dirac point. It is worth noting that, although the C atoms on graphene
connecting to PFPA retain their sp2 hybridization, the sp2 hybridization angle is
changed. As a result, the electronic structure of graphene is inevitably affected by
PFPA functionalization. An important ramification of the [2 + 1] cycloaddition
induced perturbation is that the alteration in the electronic structure of graphene
increases with incrementing PFPA functionalization concentration. We have
investigated the functionalization of graphene at a higher PFPA concentration by
including another PFPA functional group in the unit cell (see Figure 3).
Figure 3. Ball-and-stick representation of optimized structures of PFPA functionalized graphene with one and two PFPA addends in the left and right panels, respectively. d and d0 are two characteristic bond lengths of 1.56 and 1.42 Å, respectively.
12
Figure 4. Calculated band structures for pristine graphene (left panel), one-PFPA functionalized graphene (middle panel), and two-PFPA functionalized graphene (right panel). Γ = (0,0), K = (π/3a,2π/3a), M = (0,π/2a), where a = 17.22 Å for a 7 × 7 rhombus unit cell. The Fermi level is shifted to 0 eV (dashed blue line).
The results from geometry optimizations indicate that bridgehead C-C bond
breaking persists at higher concentrations. The extracted energy gap is 0.16 and
0.29 eV for one and two PFPA molecules on a graphene unit cell consisting of 98
carbon atoms, respectively. Closer scrutiny of the band alignments32 and dispersions
near the Dirac point reveals that the gap opening is primarily attributed to the
functionalization-induced modifications of the π conjugation. The disruption of the
original π conjugation is manifested in the level hybridization, as seen in the band
13
structure (Figure 4). Specifically, the highest occupied molecular orbital (HOMO) and
the lowest unoccupied molecular level (LUMO) of PFPA line up with the π and π*
bands of graphene at about -1 and 1 eV, respectively. The band alignment is such that
the interaction between flat and dispersed bands leads to hybridization induced level
avoided-crossing, which leads to the split of π and π* bands of graphene into two
hybridized bands each.
We show in Figure 5 charge densities of the corresponding hybridized bands at
the band center (the Γ point). For those states, the charge density distributions display
predominant charge confinements on PFPA molecules for hybridized conduction and
valence bands. This is to be contrasted to the conjugated π and π* pattern on graphene.
As can be seen in Figure 5, the increase of the addend concentration leads to a
proportional increase of the change of the π conjugation. This correlates with the
associated increase of the band gap and thus provides support of the suggested
scenario of the functionalization-induced band-gap opening. Careful examination of
the charge density distributions also indicates the existence of σ and σ* bonds in the
hybridized states that contribute to the gap formation as well.
14
Figure 5. Isosurface plot of charge densities of the hybridized valence band maximum (VBM), conduction band minimum (CBM), and the next near-gap states at the band center. The isovalue is 0.025 au.
1.4 Closing Remarks
A few remarks are in order. (i) The semi-metallic graphene is more sensitive to
the π-conjugation changes than the metallic single-walled carbon nanotubes. For the
latter to open a gap, it is necessary to have a higher functionalization
concentration.30,31 This appears to be attributed to the curvature of the nanotube.30 (ii)
The formation of a band gap in PFPA functionalized graphene is analogous to the
epitaxial graphene in that Stone-Wales defects and the graphene-substrate interaction
generate band gaps due to the disruption of π conjugation. (iii) In this work, we focus
mainly on the electronic structure characteristics, specifically, the mechanism of band-
gap formation for PFPA functionalized graphene. The issue of solubility of alkyl,
ethylene oxide, and perfluoroalkyl groups can be addressed by alternative theoretical
approaches, such as density functional tight-binding calculations. (iv) In addition to
15
the absence of midgap impurity states, it is worth noting that the gap formation
mechanism of PFPA functionalized graphene is qualitatively distinct from that of NH
functionalized graphene.35
We illustrate in Figure 6 the calculated band structure. As is readily observable
from Figure 6 that, although both schema lead to a gap at the Dirac point (K) that is
attributed to the functionalization-induced symmetry breaking,35 NH functionalized
graphene generates a crossing in the vicinity of the Dirac point. By contrast, the
PFPA-functionalized graphene sustains the gap formation. This clearly demonstrates
the crucial difference between NH-radical and aziridine-ring linkages. (v) The
concentration dependence of the [2+1] cycloaddition is investigated with additional
PFPA adsorption on the same side of the graphene, in accordance with an
experimental study.23 If the absorption is on two different sides of graphene, our
results indicate that the gap is still opened, but the value of the gap is almost identical
(slightly smaller) than the single adsorption. This shows that the distortion of the π-
conjugation network depends sensitively on the adsorption configurations as well.
16
Figure 6. Calculated band structures for (a) PFPA functionalized graphene and (b) NH-functionalized graphene, along with that for the pristine graphene (blue dashed lines).
1.5 Conclusions
In summary, we have studied the electronic characteristics of PFPA
functionalized graphene. We have shown that the [2+1] cycloaddition preserves the
sp2 hybridization network of the carbons on graphene. However, the π conjugation of
graphene near the Fermi level is greatly disturbed by functionalization, which leads to
the opening of a band gap dependent upon the PFPA concentration. This contrasts
with the free-radical functionalization case where the sp3-type band is induced close to
the Fermi level. Such dependence of the electronic properties on the degree of
functionalization of graphene suggests a novel and controllable method for the “band
engineering” of graphene. Our findings on the nature of a PFPA functionalization-
17
induced band gap provide useful guidelines for enabling the flexibility and
optimization of graphene-based nanodevices.
18
CHAPTER 2
SELF-ASSEMBLY OF BIOFUNCTIONAL POLYMER ON GRAPHENE NANORIBBONS
2.1 Introduction
The planar structure of graphene has potential applications in electronics,
sensor devices, spintronics, nanoelectronics, and biodiagnostics.38-42 Laterally
constraining the carriers in a quasi-one-dimensional system, graphene nanoribbons
(GNRs) can be fabricated using lithographic methods43-45 and by metal particle-
assisted46-48 or oxidative49,50 longitudinal unzipping of multi-walled carbon nanotubes
(MWCNTs). GNRs can be processed for specific applications by modification of the
basal plane and edge functional groups composed of carboxylic acid, hydroxyl,
epoxide, and carbonyl. Hydrazine significantly reduces the amount of oxygen
functional groups on GNRs, resulting in improved conductivity.49,50
Recently, significant efforts have been devised to create self-assembled
hierarchical graphene-based materials.51-53 Examples include the co-assembly of
graphene and organic monolayer,54, 55 titania nanosheets,50 and proteins.53 These
ordered structures are assembled by intermolecular forces arising from electrostatic,
π– π stacking, dipolar, van der Waals, hydrogen bonding, or metal–ligand interactions.
Various types of polymers have been shown to interact with graphene56 or graphene
oxide, forming stable hybrids.52,54 For instance, modified poly(phenylene vinylene)
19
conductive polymer can specifically attach to GNRs and tune the corresponding
electronic properties.56 In view of the rapid progress made in preparing controlled
polymer self-assembly, a better understanding of the interfacial interactions between
the helical polymer and GNRs is clearly desirable.
2.2 Results and Discussions
We have investigated the self-assembly of biocompatible polymer, R, ω-bi [2,
4-dinitrophenyl caproic] [poly(ethylene oxide)-b-poly-(2-methoxystyrene)-b-
poly(ethylene oxide)] (DNP-PEO-P2MS-PEO-DNP, hereafter referred to as m-
P2MS), onto chemically prepared GNRs. P2MS polymer with more than 20 2-
methoxystyrene monomers forms a helix rod structure.58 The m-P2MS assembles into
secondary structures in solution, resulting in associated optical activity.59 Furthermore,
the chiral initiated polymer surfaces are better supports for HeLa, mouse osteoblast,
and human osteoblast cell as compared to non-chiral initiated counterparts, owing to
the moderately periodic topography.60 Dinitrophenol groups attached at the ends of m-
P2MS are suitable for bio-sensing applications due to their high affinity to anti-DNP
IgE protein in solution and IgE on the surface of mast cells.61 The dangling glycol
end-segment is hydrophilic, aiding in the extension of the DNP groups away from the
P2MS backbone in aqueous environments, thereby assisting DNP's availability for
protein interaction. However, m-P2MS typically forms non-uniform surfaces upon
deposition on substrates. The lack of control in the formation of uniform surfaces
20
hinders the application of this type of versatile polymer. In this regard, the hierarchal
self-assembly of m-P2MS into anisotropic ordered patterns on chemically prepared
GNRs is timely and of considerable interest. This is particularly the case because
surface-adsorbed m-P2MS GNR specifically binds with anti-DNP IgE protein.
Illustrated in Figure 7 is chemical scheme ofm-P2MS, along with optimized
geometries of m-P2MS and parallel aligned P2MS chains on graphene.
While the electronic structure for graphene and GNRs is distinctive from each
other, the ensuing changes arising from the GNR edges become dormant for ribbons
with a width larger than 100 nm. Monomers of 2-methoxystyrene in Figure 7(a) were
optimized using dispersion-corrected density functional theory (DFT) method. First-
principles calculation results show that helical P2MS aligns parallel on graphene
owing to van der Waals interactions (Figure 7(b)). The calculated electronic band
structure of m-P2MS-functionalized graphene shows substantial molecular orbital
hybridization, which indicates component charge transfers. Specifically, 2-
methoxystyrene monomers in the polymer backbone serve as charge donors to
graphene.
Consequently, the helical m-P2MS chains and graphene form donor-acceptor
complex with enhanced van der Waals interactions. The diameter of m-P2MS
backbone is about 5 nm. As a result, GNRs generated from unzipping MWCNTs, with
typical width of 300-500 nm and length of a few micrometers, provide desired planar
“flatbed” for m-P2MS self-assembly. Furthermore, the oxygen groups at the GNR
21
edge and the basal plane contribute to m-P2MS self-assembly onto GNRs via
hydrogen bonding.
Figure 7. m-P2MS chemical scheme and optimized geometry. (a) Schematic representation of α, ω-bi[2,4-dinitrophenyl caproic] [poly(ethylene oxide)-b-poly(2-methoxystyrene)-b-poly(ethylene oxide)] (m-P2MS), and side views of optimized helical m-P2MS section. Helical poly (2-methoxystryene), glycol segment, and pendant 2, 4-dinitrophenyl are highlighted in red, yellow, and blue, respectively. (b) Top view of the optimized structure of attached helically P2MS on graphene (green color).
S O P
22
The m-P2MS of 1015K molecular weight (74112 repeat units) forms
aggregates of 265(35 nm diameters in tetrahydrofuran (THF) solvent, which was
confirmed by dynamic light scattering (DLS). The strong van der Waals interactions
between the m-P2MS helical rigid rods lead to the formation of polymer-specific sized
aggregates in solution. The optical rotation of polarized light by the m-P2MS
secondary polymer structures in solution, yet the formation of nonuniform films on
silicon or silicon oxide surfaces, indicates that aggregates form weakly associated
superstructures in solution. As such, GNR's adhesive properties, due to its inherent
van der Waals forces,62 make it suitable for the controlled attachment of m-P2MS
secondary polymer structures, which is of interest from the perspective of better
understanding graphene/polymer nanoscale film topography. To this effect, we have
prepared GNRs with a typical height of approximately 0.50-0.75 nm using oxidative
chemistry technique developed by Tour and co-workers.49,50 We show in Figure 8
typical atomic force microcopy (AFM) images of m-P2MS spin-cast onto single-layer
GNR adsorbed on a silicon oxide (SiO2) surface.
23
Figure 8. Supramolecular organization of polymer features on GNR showing three-dimensional AFM topography data. (a) Lamella ordered m-P2MS polymer drop-cast on the GNR. Bottom inset: structured polymer periodicity of 200 nm and height of 75 nm along the m-P2MS–GNR hybrid. (b) Aligned herringbone-shaped lamella polymer features after 24 h exposure to solvent-rich environment. Bottom inset: structured polymer periodicity of 195 nm and height of 75 nm along the m-P2MS–GNR hybrid. (c) Aligned herringbone-shaped polymer features in polymer deposited on chemically reduced GNR (r-GNR). Bottom inset: structured polymer periodicity of 150 nm with heights of 4.5–20 nm extracted from the height profile along the m-P2MS–GNR hybrid.
The m-P2MS polymer spontaneously self-assembles along the entire ribbon in
a platelet pattern (Figure 8(a)). The platelet nanopattern has a periodicity of 200 (20
nm and an overall height of 59-74 nm. The mean corrugation height along the cross
section of the hybrid ribbon is 23 (5 nm (Figure 8(a)). The gradient processed image
(inset of Figure 8(a)) displays partially overlapping polymer lamella in “scale like”
fashion along the GNR. The size of apparent platelet pattern is consistent with DLS
data that reveal similarly sized m-P2MS aggregates in THF solvent. This demonstrates
that the ∼265 nm m-P2MS secondary polymer structures attach to the graphene
surface via electrostatic and van der Waals interactions, forming supramolecular layers
and presumably further mediated by the graphene edges. In contrast, there are no
24
distinguishable ordered m-P2MS polymer structures on the amorphous SiO2 surface
(Figure 8(a)).
The nanocomposites were processed to form complex networks upon further
exposure to a solvent vapor-rich atmosphere for a 12 h period (Figure 8(b)). The m-
P2MS on the GNR spontaneously forms into aligned herringbone features on the
GNR. The herringbone pattern has a periodicity of 200 (20 nm, along with an overall
height and width of 5974 and 550 nm, respectively. The gradient processed image
(inset of Figure 2(b)) reveals a distinct herringbone pattern on the ribbon. The average
corrugation height along the cross section of the hybrid ribbon is 14 (5 nm (inset of
Figure 8(b)), a moderate reduction of film topography after solvent exposure. These
herringbone-shaped polymer features are attributed to the incorporation of solvent
vapor into the polymer matrix, allowing for increased m-P2MS chain mobility. The m-
P2MS chains are subsequently able to undergo further van der Waals mediated
adhesion to the GNR.
The chemical unzipping of MWCNTs invariably leads to the presence of
oxygen species on the basal plane and ketone groups along edges of the GNR, which
can interact with the ether groups available on the m-P2MS aggregate. The
combination of the hydrophobic P2MS chain and hydrophilic glycol terminal groups
is essential for supramolecular attachment to the GNRs. A circular dichroism
spectroscopy study of m-P2MS and the hybrid with GNRs reveals that, while the
feature of the helical rod of m-P2MS is modified slightly with the inclusion of GNRs,
the addition of water plays an important role in the enhanced interactions between m-
25
P2MS and GNRs. We demonstrate in Figure 8(c) the height tuning of the m-P2MS
polymer nanopattern on chemically reduced GNR (r-GNR). A herringbone polymer
pattern is clearly evident on r-GNR (Figure 8(c)).
The height data (inset of Figure 8(c)) profile along the P2MSr-GNR hybrid
shows the structured polymer periodicity of 150 (10 nm and an overall corrugation
height ranging from 4.5 to 20 nm. Thus, the reduction in m-P2MS surface topology is
likely related to the decrease of the oxygen functional groups, while the preservation
of the herringbone pattern can be attributed to van der Waals interaction with the
GNR. Consequently, r-GNR facilitates flexibility in controlling polymer height, while
retaining the characteristic polymer pattern on the r-GNR surface. The polymer
interaction with the GNR nanofiller was investigated using differential scanning
calorimetry (DSC) over the temperature range of 40 to 200 C·.The GNR thermogram
exhibits an endothermal transition approximately at 130 C·, which is attributed to the
release of adsorbed water. Upon further heating, the GNRs undergo an exothermal
transition at 170 C· that is associated with the thermal decomposition. The DSC
thermogram of 1% GNR loaded m-P2MS shows a melting temperature at 102 C·, an
increase of 7 C· in comparison to m-P2MS and m-P2MS loaded with 1% r-GNR,
which have melting temperatures of ∼95 C·.
The addition of low concentrations of r-GNRs has little effect on the polymer
thermal performance. The prominent endothermic peak of the GNR thermogram is
notably absent from the GNR and r-GNR polymer composite thermograms. The
composite thermograms indicate that the m-P2MS polymer hinders the release of
26
water from the GNR surface. The composites undergo exothermic deflagration
between 150 and 165 C·. The thermal performance of the composite implies that the
incorporation of the chemically prepared GNRs at low concentrations into the m-
P2MS matrix moderately inhibits the polymer chain movement, consistent with the
effect of other carbon-based fillers on polymer thermal properties.63-67
To demonstrate the potential of these polymer nanostructures as a biological
interface, we performed protein interaction studies using confocal laser scanning
microscopy and AFM. IgE is a well-studied protein known to be involved in the
body's immune response. The m-P2MS adsorbed on the GNRs retains the bioactivity
of the divalent DNP functional groups. Three-dimensional laser scanning microscope
and AFM images (Figure 9(a), (c)) show polymer ordering on the basal plane and
edges of the GNR. As seen in Figure 9(a), the polymeric structures are ordered along
the GNR. The darker region along the axis is of higher thickness in comparison to the
edges. Discernable polymeric structures yield ovate and overlapping configurations
(Figure 9(c)), forming hierarchal polymer structures at GNR basal and edge interfaces.
The ovate polymer structures have an average height, width, and length of 7.8, 336,
and 900 nm, respectively. The polymer lamella patterns appear to follow along the
smooth edges and basal plane of the macromolecular ribbon. These polymeric
structures, attached at the edges, undergo further conformational change into
secondary periodic structures on the GNR basal plane.
27
Figure 9. m-P2MS polymer ordering on GNR and IgE binding. (a) Laser confocal microscope and 3D rendering of AFM topography image of m-P2MS polymer ordering on GNR before ((a),(c)) and after ((b),(d)) IgE exposure, respectively. Inset of b: Fluorescence confocal microscope images.
The bioactivity was investigated by incubating them-P2MS GNR
nanocomposite in phosphate buffer solution (PBS) containing fluorescently labeled
Alexa 488-IgE and a blocking protein for 15 min. Fluorescent microscope images
(inset of Figure 9(b)) demonstrate lengthwise fluorescence on the nanocomposite
ribbon. Dyes attached to graphene undergo fluorescence resonance energy transfer,
which typically results in dye fluorescence quenching.62, 69 By contrast, fluorescence is
not quenched in them-P2MS GNR nanocomposite, as the polymer attached to the
GNR surface and edges acts as a spacer that keeps the fluorescently labeled IgE from
contacting the GNR surface. AFM topography images in Figure 3(d) reveal that the
IgE protein clusters at the edges of the polymer structures on the GNR. The DNP
groups being accessible to anti-DNP IgE in the solid state is relevant for biosensing
28
applications. The features showing IgE protein edge clustering indicate that the DNP
groups are spatially confined at the edges of the polymer superstructures and available
for protein interactions. It is worth noting that protein fibrils propagate from the edges
of the polymer structures. The height profile (inset of Figure 9(c)) of the P2MS GNR
hybrid shows a periodicity of 270 (50 nm and an average corrugation height of 25 (5
nm. Subsequent to the IgE exposure, the composite ribbon has a periodicity of 100 (35
nm and an average corrugation height of 15 (5 nm (inset of Figure 9(d)). The decrease
in surface roughness is attributed to the addition of IgE protein.
A typical Raman spectroscopy (433 nm laser excitation) graph for the GNR
polymer hybrid composes a graphene (G) band (1603 cm-1) and a graphene defect (D)
band (1354 cm-1) of roughly equal size (Figure 10(b)). Four bands observed from 2600
to 3200 cm-1 are typical of chemically prepared GNRs.50 Adsorption of polymer
retains the characteristic Raman spectroscopy G band and D band peaks. Shown in
Figure 10 is a microscope image of m-P2MS/GNR composites, on a silicon oxide
substrate, which have been exposed to a solvent atmosphere over a period of a week.
Remarkably, the polymer features are spatially confined the approximate width of a
GNR (light blue) and anisotropically extend beyond the footprint of the GNRs by
several micrometers. Micro-Raman mapping with a spatial resolution of 1 µm was
used to investigate the polymer surface features.
29
Figure 10. Multi-micron polymer ordering on GNR. Long-range polymer ordering of P2MS centered on GNR, propagating on SiO2. The composite feature is typically 10 µm in length and 1 µm in width. Inset: Micro-Raman map spectroscopy of the peak width of the G (1603 cm–1) line intensity acquired on a 12 × 8 µm scan window highlighted by the red box.
The Raman mapping of the G line (1603 cm-1) peak (inset of Figure 10) shows
that the center point of the polymer feature (yellow region) is unambiguously assigned
to GNRs. These results confirm that the GNRs are capable of controlled propagation
of m-P2MS over several micrometers on a SiO2 surface, and the polymer structure
retains the approximate width of the nucleating GNR. Understanding charge transfer
at the polymer/graphene interface and the spatial distribution of the resultant charge
carriers is important to the development of graphene-based devices. Interestingly,
density functional calculations show that charge accumulates at the m-P2MS chain
ends for the valence band states of the m-P2MS GNR nanocomposite. Graphene
preferentially maintains a charge-neutral molecular orbital level.70-73 Consequently,
the energy level alignment relaxation of doped graphene induces optimal charge
30
redistribution from the length of the polymer chain to the m-P2MS chain ends, leading
to the electrostatic joining of the charged m-P2MS chain ends. The induced charge
transfer between m-P2MS and GNRs promotes long-range attractions, thus allowing
the preferred alignment of m-P2MS chains. It is worth mentioning that the planar
topography and the smooth edges of GNRs play an important role in the self-assembly
process. This is in contrast to the deposition of m-P2MS on highly ordered pyrolytic
graphite (HOPG), in which no regular m-P2MS polymer self-assembly pattern is
observed. These observations strongly suggest that GNR facilitates the controlled
assembly of m-P2MS, owing to enhanced van der Waals interactions and its unique
planar conformation with regular edges.
2.3 Methods
The MWCNTs were unzipped and reduced using an optimized method
developed by Tour and coworkers.49 A modified GNR purification procedure was
utilized, in which the product was isolated by repeated mixing and centrifugation
steps, for the separation of exfoliated graphene ribbons from unzipped MWCNTs. The
oxidation reaction product was poured into 5 mL of liquid nitrogen cooled 30%
hydrogen peroxide, which prevented the precipitation of potassium permanganate. The
resultant single and bilayer GNRs were spin-cast from an ethanol/water (50:50)
solution onto a silicon wafer with 300 nm SiO2 wafers. The GNRs were reduced by
their adsorption on the SiO2 surface and subsequent treatment with 1 vol% hydrazine
monohydrate and 1 vol% concentrated ammonium hydroxide. The reduced GNRs
31
were washed with de-ionized water and dried under nitrogen gas flow. Protein Binding
was initiated via the m-P2MS/GNR composites adsorbed on a silicon oxide wafer
were sensitized with Alexa488-IgE containing 1 mg/mL of BSA for about 15 min,
which were subsequently washed in phosphate buffer solution (PBS) containing BSA.
2.4 Conclusions
We have described a method for controlled nanopatterning of GNRs by the
self-assembly of m-P2MS onto the GNR surface. The m-P2MS self-assembly on the
GNRs is attributed to van der Waals interaction between the GNR basal plane and the
m-P2MS backbone. The present investigation provides a basis for studying polymer
surface topology on GNRs and the associated effect on protein binding.
32
CHAPTER 3
THEORETICAL INVESTIGATION OF PEROXIDE SYNTHESIS USING ATOMIC NEGATIVE IONS
3.1 Introduction
The exploration of the role of atomic particles and nanoparticles in catalysis
has attracted a wide range of fundamental and industrial investigations.75-89 In
particular, the direct synthesis of hydrogen peroxide from H2 and O2 using supported
Au, Pd, and Au–Pd nanoparticle catalysts has been reported.81,89 The experiments
found that the addition of Pd to the Au catalyst increased the rate of H2O2 synthesis
significantly as well as the concentration of the H2O2 formed. These findings have
motivated us to study at the fundamental atomic physics level the mechanism
underlying the Au and Pd nanoparticles’ excellent catalytic properties.80,81 including
the substantial enhancement of the Au–Pd nanocatalyst over the individual Pd and Au.
Recently, we investigated the transition state of the oxidation of water to peroxide by
performing dispersion-corrected density-functional theory calculations on the catalytic
properties of atomic Au– and atomic Pd– negative ions.92 From the results, we
concluded that the atomic Au– negative ion catalyst will most likely catalyze a reaction
whenever water is the medium, but the atomic Pd– negative ion catalyst acts as the
33
most efficient and economical catalyst when compared to the atomic Au– negative ion
catalyst.
In this study, we want to obtain definitive answers to the following questions:
(1) Can these catalysts, namely, atomic Au– and atomic Pd– negative ions, efficiently
catalyze heavy water to heavy peroxide? (2) How does the performance of these
negative ion catalysts compare when catalyzing H2O2, HDO2, and D2O2 from H2O,
HDO, and D2O, respectively?
Answers to these questions could provide valuable insight into the bond
strengths in H–O–H, H–O–D, and D–O–D. Toward this end, we have investigated and
compared the catalysis of H2O, HDO, and D2O conversion to H2O2, HDO2, and D2O2,
respectively. Deuterium (D) is obtained by combining two nuclei of hydrogen via
nuclear fusion at very high temperature. Deuterium is unique among heavy stable
isotopes in being twice as heavy as the lightest isotope. This difference increases the
strength of water’s H–O bond, and in turn, this is sufficient to cause differences that
are important to some biochemical reactions.98 Deuterium can replace the light
hydrogen in water molecules to form heavy water (D2O), which is about 11% denser
than normal water (this is enough that ice made from it sinks in ordinary water).99
Biologically, this difference means that large amounts of heavy water can have
harmful effects on animals, although it would entail approximately 2 weeks of
consuming only D2O and no H2O to be terminal to humans. It has been found that H2O
has a longer intramolecular O–H bond length than D2O’s corresponding O–D bond
34
length. Specifically, the O–H bond is longer by about 0.03 Å, or 3%. Also, the
intermolecular hydrogen bond that connects two separate molecules is shorter in H2O
than in D2O. Here, the difference is about 0.07 Å, or 4%. Geometrical differences
between the structures of light and heavy water also exist.
Previous research predicted an overall broadening of the H2O structure
compared to the D2O structure. The hydrogen molecule and its isotopomers, HD and
D2, are of interest because of their presence in tokomak edge plasmas, planetary
atmospheres, and different astrophysical environments.95 Recent interest in deuterated
hydrogen includes the isotope effect,96 electron-impact cross sections,95 the question
of the ability of fruit flies to sniff out heavy hydrogen,98 and the sensitivity of the
endohedral translation–rotation dynamics to the differences in the interaction
potentials, including to the large variations in the masses and the rotational constants
of H2, HD, and D2 inside C60.97 The strength of hydrogen bonds per water molecule is
less in H2O than in D2O (3.62 eV vs 3.76 eV). Together, these structural differences
give light water a broader structure and heavy water a narrower, tetrahedral shape.98 In
the formation of H2O2, HDO2, and D2O2, we have also calculated the corresponding
transition states with and without the presence of the atomic negative ion catalysts. We
found that the entropy decreases when moving from H2O → HDO → D2O because of
the higher average number of hydrogen bonds per molecule and bond length
contribution to the ordering of the molecules. Additionally, in this study, we consider
the catalytic effect of both the Au– and Pd– ions on the oxidation of the light,
35
intermediate, and heavy water to the corresponding peroxides from a fundamental
approach through the combined theoretical atomic physics and the quantum chemistry
perspectives.90-92
3.2 Theoretical Overview
The Regge-pole methodology 99 has been employed to explore, through the
elastic total cross sections (TCSs), the near–Threshold scattering of slow electrons
from both the ground and excited states of simple and complex atoms.100-103
Embedded in the Regge-pole methodology are the crucial electron–electron
correlations and the vital core polarization interactions. These physical effects are
responsible for the existence and stability of typical negative ions. It has been found
that Ramsauer–Townsend (R–T) minima, shape resonances, and the dramatically
sharp long-lived resonances characterize the low energy electron elastic scattering
TCSs. From the electron energy positions of the very sharp long-lived resonances, the
important binding energies (BEs) of the resultant negative ions formed during the
collisions as Regge resonances have been extracted. These binding energies are
identified with the EAs of the relevant atoms when the binding energies correspond to
the negative ions formed in the ground state.
Very recently, the same fundamental mechanism that underlies the well-
investigated muon-catalyzed nuclear fusion using deuterium (D) and tritium (T) has
been proposed to drive nanoscale catalysis.90,91 The fundamental atomic mechanism
36
responsible for the oxidation of water to peroxide has been attributed to the interplay
between Regge resonances and R–T minima in the electron elastic TCSs for Au and
Pd atoms, along with their large electron affinities.90 Furthermore, dispersion-
corrected density-functional theory (DFT) transition state calculations have been
performed on the atomic Au– and Pd– ion catalysis of water conversion to H2O2,
revealing the important role played by the formation of the Au–(H2O)2 and Pd–(H2O)2
anion molecular complexes.105
The formation of these anion complexes in the transition state, with the
interaction of the Au– and Pd– ions with H2O being comparable to the strong hydrogen
bond, has been identified as the fundamental mechanism, as shown in Figure 11, for
breaking the hydrogen bonding strength in the catalysis of H2O2 using the atomic Au–
and the atomic Pd– ions. Thus, the crucial link between low-energy electron elastic
scattering resonances and low-energy chemical reaction dynamics has now been fully
established.92 In the H2O2 catalysis, the anion Au–(H2O)2 molecular complex formed
during the transition state weakens (breaks) the H–O bonds, thereby promoting the
formation of the H2O2 in the presence of O2. This important mechanism can also be
used to understand the experiments with ozone gas that have demonstrated that
bacteria and viruses were torn apart, with the Ag acting as an extremely efficient
oxidative catalyst.106
37
Figure 11. Catalytic cycle of the oxidation of heavy water to heavy peroxide through the atomic Au– negative ion catalyst.
3.3 Reaction Dynamics
Following reference 90, in this study, we first consider the slow oxidation of heavy
water to heavy peroxide without the atomic negative ion catalyst
(1) 2D2O + O2 → 2D2O2
Then, we apply the atomic Au– negative ion to speed up reaction 1 and obtain
(2) Au- (D2O) 2 + O2 →Au- + 2D2O2
(3) Au- + 4D2O + O2 →Au- (D2O)2 + 2D2O2
Then, we add reactions (2) and (3) and obtain
(4) 4D2O + 2O2 → 4D2O2
Reactions (2) and (3) are captured in the self-explanatory Figure 11 for clarity.
A similar result as in equation 4 is obtained when the atomic Au– negative ion catalyst
38
is replaced by the atomic Pd– negative ion catalyst and when the H2O and HDO
molecules are used. Note, it is important to introduce the Au- ion into the (D2O2)2
before adding the O2 as in Equation (2). The question we want to address here is
which of the two negative ion catalysts is more effective in the catalysis of the heavy
water to peroxide. The anionic complexes Au–(H2O)2 and Pd–(H2O)2 have been
characterized as atomic Au– and atomic Pd– negative ions interacting with two water
molecules, respectively, i.e., as anion–molecule complexes.105 The large electron
affinities of atomic Au and atomic Pd played the essential roles; they are important in
the dissociation of the Au–(H2O)2 and Pd–(H2O)2 complexes breaking up into atomic
Au– or atomic Pd– negative ion and (H2O)2, respectively.105 Very important here, the
experiment84 found a stronger interaction between the atomic Au– negative ion and
H2O and that the atomic Au– negative ion does not react with O2. Similar reactions as
in Equations (1)–(4) can be generated when the heavy water, D2O, is replaced by the
intermediate water, HDO, and a figure similar to Figure 11 can be generated as well.
3.4 Thermodynamics of Reactions
In the H2O2 catalysis from water using the atomic Au– negative ion, the
hydrogen-bond-breaking mechanism has been attributed to the formation of the
complexes involving the atomic Au– negative ion and two water molecules. Water
possesses the unique properties that are rare in other materials and are of biological
importance. These properties are evident in hydrogen bonded environments,
39
particularly in liquid water. In liquid water, the hydrogen bond’s enthalpy is
approximately 0.24 eV and the total dissociation energy is 5.09 eV. Hydrogen bonding
has a direct impact on the change in the Gibbs free energy, G (∆G = ∆H – T∆S),
where H, T, and S represent enthalpy, temperature, and entropy, respectively. When
the atomic negative ion catalyst is introduced into the oxidation of water, there is
breaking of hydrogen bonding. Therefore, the system changes from relative order to
disorder. Hence, the entropy of the system increases, whereas the enthalpy of the
system decreases. The overall result leads to the Gibbs free energy being negative, and
the process results in the spontaneous formation of peroxide. To gain a deeper
understanding of the process of atomic negative ion catalysis, we have also calculated
the rate of a reaction using the Arrhenius equation.107
3.5 Calculations Utilizing CAM Theory, and Transition State Theory
For the calculation of the elastic scattering TCSs for the atoms of interest here
(Au and Pd), we have used the Mulholland formula, in atomic units, implemented
through the complex angular momentum (CAM) description of electron-atom
scattering.99
We have furthermore employed the first principles calculations based on
density functional theory (DFT) and dispersion-corrected DFT approaches. For
structural molecular confirmation, we further utilized the generalized gradient-
corrected approximation (GGA) Perdew–Burke–Ernzernof (PBE) parametrizations of
40
the exchange-correlation functional, along with the double numerical plus polarization
basis set as implemented in the DMol3 package.36,37 The calculations used a tolerance
of 1.0 × 10–3 eV and a basis set cutoff of 0.4 nm for the energy convergence. To assess
the relativistic effects, we have also recalculated the transition barriers with the use of
an all-electron relativistic potential. The resulting energy barriers were found to be
2.63, 3.02, and 3.37 eV for H2O, HDO, and D2O, respectively. However, the use of the
nonrelativistic potential yields 2.69, 3.07, and 3.39 eV, respectively.
The relativistic effects contribution is seen to be small, less than 2.3%. The
dispersion correction is based on the Tkatchenko–Scheffler (T–S) scheme,108 which
exploits the relationship between polarizability and volume. The T–S dispersion
correction takes into account the relative modification in dispersion coefficients of a
variety of atomic bonding by weighting values extracted from the high-quality ab
initio database with atomic volumes derived from the partitioning of the self-
consistent electronic densities. The T–S scheme has been successfully applied to a
variety of systems for a much improved accuracy. The physical effects of electron–
electron correlations and the core polarization interactions are vital for the existence
and stability of typical negative ions.
Consequently, this justifies the adoption of the dispersion-corrected atom-
centered potentials (DCACPs) for use in the present calculations of the atomic Au–
and atomic Pd– negative ion catalysis of light, intermediate, and heavy water to the
corresponding peroxides. The Kohn–Sham formalism of density functional theory
41
(DFT) combined with many popular approximated exchange-correlation functionals
inadequately accounts for the vital London dispersion forces that are of crucial
importance in chemical and biological systems.109
When an effective atom-centered nonlocal term was added to the exchange-
correlation potential in order to cure the lack of London dispersion forces in standard
DFT,110 the corrected generalized gradient approximation DFT calculations yielded
correct equilibrium geometries and dissociation energies of argon–argon, benzene–
benzene, graphite–graphite, and argon–benzene complexes. The DCACPs have been
tested by evaluating the interaction energy of different weakly bound molecular
systems (P2, PH3, and PN dimers) and applied successfully to phosphorus as well.107
The ability of DCACPs to improve the GGA treatment of hydrogen-bonded systems
has been confirmed for the hydrogen bond lengths and binding energies of 20
complexes containing the elements C, H, N, O, and S.112 It was concluded that
DCACPs improve significantly the BLYP description of hydrogen-bonded systems.
The application of the DCACPs to the study of liquid water leads to a softening of
liquid water’s structure, resulting in higher mobility.
This demonstrates that van der Waals interactions are essential in fine-tuning
both structural and dynamical properties of liquid water.113 Also, the convergence to
the correct long-range asymptotic behavior of the multicenter expansion for DCACPs
has been demonstrated in the case of the H2 van der Waals dimer.114 A transition-state
search employing nudged elastic bands facilitates the evaluation of energy
42
barriers.108,115-119 After the initial construction of the reaction path, a transition-state
search followed by a transition state optimization was performed using the linear
synchronous transit (LST) method and the quadratic synchronous transit (QST). In
addition, we have performed a vibrational analysis of the transition state and
confirmed that that the transition state has only one imaginary frequency associated
with it.
3.6 Rate of Reaction Calculation
We have used the Arrhenius equation107 to calculate the rate of a reaction and
compared the number of molecules that can react in the absence and presence of the
atomic negative ion catalyst at constant (room) temperature using the expression (5)
where K is the rate constant, T is the temperature in kelvin, R is the gas constant
8.31 J•mol/K, Ea is the activation energy in J•mol, and A is the frequency factor
which includes factors such as the frequency of collisions and their orientation. It
varies slightly with temperature, although not much. It is often taken as constant
across small temperature changes.
3.7 Results and Data
In our recent study, we investigated the catalytic properties of both atomic Au–
and atomic Pd– ions when catalyzing H2O2 from H2O from the atomic physics
perspective. The low energy electron elastic TCSs for both Au and Pd atoms are
43
characterized by two R–T minima as shown in Figure 12;90,102 the most important one
in this context being the second local R–T minimum. Table 1, taken from reference
85, shows the first R–T minima for Au at 0.692 eV and for Pd at 0.930 eV to be much
higher than the corresponding second minima at 2.057 eV for Au and 3.134 eV for Pd.
As shown in Figure 12, we note that the excited-state TCSs for both atomic Au and
atomic Pd, characterized by huge deep R–T minima, followed by shape resonances,
typify the ground-state electron elastic collision cross sections for many atoms.98, 99
Sitting at 2.262 and 1.948 eV in very close proximity to the second local R–T
minimum of atomic Au are the bound states of the atomic Au– and atomic Pd–
negative ions, respectively (see reference 90). The observed81,89 exceptional catalytic
property of both nano Au and nano Pd has been attributed to the unique positioning of
the second local R–T minimum of atomic Au together with the resonance at around
the same position. The importance of the R–T minimum as already indicated in
reference 85 is to facilitate the creation of new molecules. At this minimum and
appropriate environment, the attachment of the atomic Au– negative ion to (H2O)2 can
result in the formation of the Au–(H2O)2 anion complex at a BE of about 3.20 eV and
characterized as a gold anion interacting with two water molecules.105 The BE value
corresponds to the vertical detachment energy (VDE) of the Au–(H2O)2 anionic
complex.
Figure 12. Electron Affinity calculations in eV within the crossY,Ru, Ag represented in purple, green, pink, and light blue, respectiv
. Electron Affinity calculations in eV within the cross-Y,Ru, Ag represented in purple, green, pink, and light blue, respectiv
44
-sections of Au, Y,Ru, Ag represented in purple, green, pink, and light blue, respectively.
45
Table 1.
Calculated Electron Affinities (EAs) and R–T Minima, in eV, for the Atomic Pd and Au Ground States.
The proposed mechanism of catalysis, using the atomic Au– negative ion
catalyst as an example, is as follows. When an electron collides elastically with a
ground-state neutral gold atom, attachment can result, leading to the formation of a
negative ion resonance due to the formation of compound atomic states. The energy
position of this negative ion resonance corresponds to the stable bound state of the
atomic Au– negative ion formed during the collision as a resonance. The BE of the
atomic Au– negative ion defines the EA of atomic Au. The energy position of the
atomic Au– negative ion is roughly at the second local R–T minimum of the TCS for
Au, where two H2O molecules can attach to the atomic Au– negative ion through
strong resonances with large rates forming the Au–(H2O)2 anion molecular complex.
The atomic Au– negative ion breaks the hydrogen bond and is released after the
chemical reaction. We note that the dissociative energy of the Au–(H2O)2 molecule is
about 3.20 eV. This energy is within the effective range of the second local R–T
46
minimum of the electron elastic TCS of the Au atom. From the studies in references
90 and 91, we understood the exceptional catalytic nature of the gold negative ion
from the atomic physics perspective. What is important and revealing in those studies
90, 91 is the appearance of the ground state of the atomic Au– negative ion at the second
local R–T minimum of the atomic Au TCS. Clearly, this demonstrates the importance
of identifying and delineating the resonances as well as the minima in low-energy
electron elastic collisions with neutral atoms. The same analysis applies to the atomic
Pd– negative ion catalyst. The study 90 cannot be deemed complete if we cannot
understand the problem of anion catalysis of H2O2 from H2O using the atomic Au– and
atomic Pd– negative ions from the theoretical chemistry perspective.
Thus, to address this problem, we have performed dispersion-corrected
density-functional theory for transition state (TS) calculations of the catalytic
properties of the atomic negative ions Au– and Pd– for the oxidation of light,
intermediate, and heavy water to corresponding peroxides. Figures 13 and 14 present
the optimized structures of the reactants, transition states, and products (EP) of
oxidation of intermediate and heavy water, respectively to corresponding peroxides
when the atomic Au– and atomic Pd– negative ion catalysts are absent and when they
are present. The red, white, dark blue, gold, and green spheres represent, respectively,
oxygen, hydrogen, deuterium, gold, and palladium atoms; the transition states and
products of oxidation are in eV. Table 2 summarizes the results of Figures 13 and 14.
47
Table 2.
TS and EP represent, respectively, the calculated transition state and energy of the products, all in eV.
48
Figure 13. Optimized structures of (a) intermediate water (HDO), (b) intermediate water catalyzed by atomic gold negative ion to peroxide, and (c) intermediate water catalyzed by atomic palladium negative ion to peroxide, along with corresponding energies of reactants, transition states (TS), and products (EP). O, H, D, Au–, and Pd– are represented by red, white, dark blue, gold, and green, respectively.
49
Figure 14. Optimized structures of (a) heavy water oxidation, (b) heavy water catalyzed by atomic gold negative ion to peroxide, and (c) heavy water catalyzed by atomic palladium negative ion to peroxide, along with corresponding energies of reactants, transition states (TS), and products (EP). O, D, Au–, and Pd– are represented by red, dark blue, gold, and green, respectively.
50
To determine the effect of the solvent on the calculations, we have used the
COSMO solvation model for the transition state calculations. For example, when the
atomic Au– negative ion catalyst is used, the resultant energy barrier for HDO is 3.02
eV (all-electron relativistic), 3.05 eV (with COSMO), and 3.07 eV (non-relativistic
potential). This demonstrates that the effect of the solvent is negligible.
3.8 Discussions
3.8.1 The Atomic Physics Analysis
We first consider the slow oxidation of light water to peroxide in the absence
of the atomic negative ion catalyst. Upon the addition of the atomic Au– or atomic Pd–
negative ion to H2O, an anionic complex is formed at the second local R–T minimum
of the TCS with a transition state Au–(H2O)2 or Pd–(H2O)2, respectively. Then, the
large EAs of the Au and Pd atoms play the important roles in the breaking up of the
complex to form the atomic Au– or atomic Pd– negative ion and H2O2 products. These
atomic Au– and atomic Pd– negative ions weaken/break the hydrogen bonding in the
H2O, thereby allowing the additional O2, usually provided by the support to attach to
form the desired H2O2. The same argument applies to the oxidation of HDO and D2O
to HDO2 and D2O2, respectively. Although the first and second local R–T minimum in
the TCSs for both atomic Au and atomic Pd are qualitatively the same, including their
EAs as indicated in Figure 12,90 there is little understanding why the atomic Pd–
negative ion has a higher catalytic activity than the atomic Au– negative ion.
51
3.8.2 Thermodynamics Calculation
The entropy of a system increases as it becomes more disordered. For
convenience, we use the case of H2O as an illustration. In the presence of the atomic
negative ion catalysts such as the atomic Au– negative ion, the complex Au–(H2O)2 is
formed in the transition state. In this anionic complex, the two water molecules are
attached to an atomic Au– negative ion. By definition, a catalyst speeds up the rate of a
reaction by lowering the activation energy without changing the energy of the
reactants and the products. Also, the activation energy is the minimum energy required
for a reaction to take place. We followed the steps below to calculate the percentage of
H-bond strength broken when we applied the Au– (Pd–) anion catalyst:
(1) In liquid water, for example, the energy of attraction between water molecules
(hydrogen bond enthalpy) is approximately 0.24 eV.
(2) Our results indicate that the energy of a product changes from 2.21 to 2.13 eV
when we apply the Au– anion catalyst and to 2.04 eV when we apply the Pd– anion
catalyst.
(3) These results can be explained through the percentage of H-bond strength broken
upon the application of a catalyst to the system.
For example, when the atomic Au– negative ion catalyst is used, we obtain:
The percentage of H-bond strength broken is approximately 30%. A similar result is
obtained when the atomic Pd– negative ion catalyst is used; it is equal to 50%.
Therefore, at least 30% of the H-bond strength is broken when the atomic Au–
52
negative ion catalyst is applied, while the percentage increases to 50% with the
replacement of the atomic Au– negative ion by the atomic Pd– negative ion catalyst in
the oxidation of H2O to H2O2. Indeed, these results are consistent with the findings in
the measurements using nanoAu and nanoPd catalysts.81, 89
With the replacement of H by D in the water molecule, the contribution of H-
bonding and the bond length change. Upon the introduction of the atomic negative
ions into the reactions, the entropy of the system increases and its enthalpy decreases.
This leaves the change in Gibbs free energy more negative, resulting in
thermodynamically favorable formation of peroxide.
Figure 15 contrasts the change in entropy (cal/mol•K) versus temperature, T
(K), for the oxidation of D2O to D2O2. The black, pink, and green curves represent the
oxidation of heavy water to peroxide in the absence of a catalyst, in the presence of
atomic Au–, and in the presence of atomic Pd– negative ion catalysts, respectively.
Clearly, the addition of the atomic Au– negative ion catalyst increases the ∆S
significantly throughout the range of temperatures. This is indicative that the atomic
Au– negative ion catalyst disrupts the D-bond and this disruption increases ∆S with the
temperature as expected. The addition of the atomic Pd– negative ion catalyst to the
D2O increases the change of enthalpy even higher compared to the case when the
atomic Au– negative ion catalyst was added, green curve in Figure 15.
Figure 15. Change in entropy, of D2O to D2O2. The black, red, and green curves represent the oxidation of heavy water to peroxide in the absence of a catalyst and in the presence of atomic Auatomic Pd– negative ion catalysts, respectively.
Figure 15. Change in entropy, ∆S (cal/mol•K), vs temperature, T (K), in the oxidation . The black, red, and green curves represent the oxidation of heavy
water to peroxide in the absence of a catalyst and in the presence of atomic Aunegative ion catalysts, respectively.
53
S (cal/mol•K), vs temperature, T (K), in the oxidation . The black, red, and green curves represent the oxidation of heavy
water to peroxide in the absence of a catalyst and in the presence of atomic Au– and
54
3.8.3 Hydrogen Bonding Calculation
Using the EP differences from Table 2, the hydrogen bonding (HB) of H2O,
HDO, and D2O is calculated utilizing density functional theory; the results are
presented in Table 3. The results indicate that regardless, in the absence and presence
of the atomic negative ion catalysts, the HBs of HDO and D2O are about 10 and
15.6% greater than that for H2O, respectively. The results are consistent with the
previous finding.
Table 3.
Calculated energy barrier, (EB), and hydrogen bonding, (HB), in eV
3.8.4 Rate of Reaction Calculation
In this study, we have also interpreted the energy barrier difference in terms of
the rate of a reaction by using the Arrhenius equation.107 In the equation, the rate of a
reaction depends on the number of collisions, orientation, activation energy, and
temperature. To understand the catalytic effect of the atomic Au– and atomic Pd–
negative ions, we assume the temperature to be 298 K and the activation energy to be
55
in eV. For example, the activation energy and the rate constant upon the action of the
atomic Au– negative ion catalyst is Ea1 = 0.54 eV and 7.58 × 10–10, respectively. Upon
the action of the atomic Pd– negative ion catalyst, these quantities become Ea2 = 0.18
eV and 9.3 × 10–4, respectively, for the oxidation of ordinary water. On the basis of the
extracted energy barriers, one can estimate that there are 1.22 × 106 more molecules
that react in the presence of the atomic Pd– negative ion catalyst compared to the case
when only the atomic Au– negative ion catalyst is present.
To find the energy barrier (EB), the EP was subtracted from the TS (refer to
Table 2), and the results are presented in Table 3. Our results show that, regardless of
whether light or heavy water molecules are being catalyzed, the atomic Au– and
atomic Pd– negative ions catalyze the reactions differently.
For example, if we compare the ratio of EB (no catalyst/ (atomic Au– negative
ion catalyst)), it is equal to 3.2, 2.4, and 1.8 for the oxidation of H2O, HDO, and D2O,
respectively. Also, the ratio of EB (atomic Au– negative ion catalyst/ (atomic Pd–
negative ion catalyst)) is equal to 3.0, 2.6, and 2.1 for the oxidation of H2O, HDO, and
D2O, respectively. It can then be concluded that, although the atomic Au– negative ion
catalyst speeds up the oxidation of water to peroxide, the atomic Pd– negative ion
possesses a higher catalytic activity than the atomic Au– negative ion when catalyzing
light, intermediate, and heavy peroxide consistent with the recent experimental
findings.81,89 Both the negative ion catalysts increase the EB of H2O such that EB
(H2O) < EB(HDO) < EB(D2O).
56
3.8.5 Relativistic Effects
A comment on relativistic effects in the calculations of the structure and the
dynamics of atomic Au and its negative ion Au– is appropriate. In calculating the
electronic structure of atomic Au and atomic Au– and their interactions, relativistic
effects are known to be important; see Gorin and Toste79 and Hakkinen et al.120 and
references therein. However, accounting for relativistic effects does not necessarily
guarantee reliable results, if the crucial electron–electron correlation effects and the
core polarization interaction, vital for the existence and stability of most atomic
negative ions, are not adequately accounted for. Most existing theoretical methods
used for calculating the binding energies of the atomic negative ions, including the
atomic Au– negative ion, are structure-based. Generally, for negative ions, the diffuse
nature of the orbitals translates into the need for an extensive partial wave expansion;
this makes calculations intractable in most cases, particularly for heavy and complex
systems. Thus, one is forced to truncate the expansion and/or selectively include what
are estimated to be the most relevant contributions. This approach is indeed adopted
by nearly all structure-based calculations, and the results obtained through these
methods are often riddled with uncertainties and lack definitiveness for complex
systems, such as the Au and Pt atoms.
57
3.9 Summary and Conclusion
We have performed dispersion-corrected density-functional theory calculations
for transition states to investigate the effect of the atomic Au– and atomic Pd– negative
ion catalysis on the formation of peroxides from H2O, HDO, and D2O. We found that
in all three cases both the atomic Au– and atomic Pd– negative ions exhibit excellent
catalytic properties in the formation of H2O2, HDO2, and D2O2. These atomic negative
ions speed up the reactions by lowering the activation energy, with the atomic Pd–
negative ion accomplishing the catalysis by a factor of about 3 times faster than that
by the atomic Au– negative ion. We have also used the Arrhenius equation to calculate
the rate of reactions and compared the number of molecules that can react in the
absence (presence) of an atomic negative ion catalyst at constant room temperature
and found that about 1.22 × 106 times more molecules react in the presence of the
atomic Pd- negative ion compared to when the atomic Au– negative ion catalyst is
present. Using the EP differences from Table 3, the hydrogen bonding (HB) of H2O,
HDO, and D2O has been calculated.
The results indicate that, regardless of the presence (absence) of the atomic
negative ion catalysts, the HBs of HDO and D2O are about 10 and 15.6% greater than
the HBs of H2O, respectively. Furthermore, upon the introduction of the atomic
negative ion catalysts to the reaction, we find that as we go from D2O → HDO → H2O
the entropy of the system increases while the enthalpy of the system decreases. This
58
leaves the ∆G more negative, resulting in thermodynamically favorable formation of
peroxide.
Previously, it was demonstrated that slow electron-Au and electron-Pd
collisions form the atomic Au– and atomic Pd– negative ions.90 Then, through the
transition state, the anionic molecular complexes Au–(H2O)2 and Pd–(H2O)2 are
formed. In the anionic molecular complex formation, the Au– and Pd– ions break up
the hydrogen bond strength in the two water molecules, permitting the formation of
H2O2, HDO2, and D2O2 in the presence of O2 usually provided by the support. These
results, together with those of references 90−92, now complete the fundamental
understanding of negative ion catalysis, at the atomic physics and chemical reaction
dynamics levels.
Namely, the negative ion resonances formed in the electron elastic scattering
TCSs with neutral atoms and transition state chemistry provide the mechanism for
negative ion catalysis. In conclusion, this important mechanism of negative ion
catalysis can now be used to understand the experiments with ozone gas in the
demonstration that bacteria and viruses were torn apart, with the Ag acting as an
extremely efficient oxidative catalyst.106 The atomic Ag– negative ion binds two water
molecules, breaking the strong hydrogen bonding; the oxygen from the ozone can then
attach to the water molecules to form hydrogen peroxide, the desired oxidation
product for bacteria or viruses destruction.
59
CHAPTER 4
GOLD ANION CATALYSIS OF METHANE TO METHANOL WITHOUT CO2 EMISSION
4.1 Introduction
Considerable efforts continue to be devoted to finding ways to reduce CO2
emissions and atmospheric concentrations. Carbon sequestration, improving the
efficiency of energy use, and reducing the carbon content of fuels are three major
pathways that are currently being pursued to address the stabilization of greenhouse
gas concentrations.125 Carbon sequestration uses various approaches for CO2 capture,
storage, and reuse.125,126 One such process, CO2 mineralization, uses carbonic
anhydrase enzyme to convert dilute, unseparated CO2 to HCO3 and finally to
everlasting calcium and magnesium carbonates. Biogenic methane is another of the
carbon sequestrations; it involves geologic storage of CO2 in depleting and depleted
oil and gas reservoirs, with subsequent conversion of the CO2 to CH4 via designer
microbes or biometric systems that operate above or below ground.125 Common among
many of these concepts is the enhancement of naturally occurring biochemical and
geochemical processes through the identification and replication of natural processes
for the purposes of carbon sequestration.
60
The catalytic partial oxidation of methane into valuable products is of great
scientific importance and considerable industrial, economic, and environmental
interest. However, a great challenge is that in the absence of an appropriate catalyst,
methane undergoes complete combustion yielding carbon dioxide and water at
approximately 340 K with minimal competition with the formation of useful products
that can occur at elevated temperatures. The fundamental ideas of muon-catalyzed
nuclear fusion utilizing a negative muon, a deuteron, and a triton127 are used in the
proposed oxidation of CH4 to methanol for which we have selected the atomic gold
anion as the catalyst. Here we propose the use of the atomic Au− ion catalyst to control
the temperature of the oxidation of methane to methanol around 325 K. This has the
effect of lowering the transition state (TS) by 32 % compared to the case of the
absence of the catalyst for the complete oxidation of methane to methanol without
carbon dioxide emission. We have employed the first principles density functional
theory (DFT) and dispersion-corrected DFT calculations for the transition state on the
Au− ion and analyzed the thermodynamics properties of the reactions as well.
The main motivations for the investigation are: (1) the direct synthesis of H2O2
from H2 and O2 using supported Au, Pd, and Au–Pd nanoparticle catalysts128,129
including the theory130,131 that attributed the catalytic properties of Au and Pd to the
formation of negative ion resonances in low-energy electron elastic total cross sections
(TCSs) for Au and Pd atoms, along with their large electron affinities (EAs); (2) the
61
recent dispersion-corrected density functional theory transition-state calculations
performed on the atomic Au− ion catalysis of water conversion to H2O2, revealing that
the formation of the Au−(H2O)2 anion molecular complex in the transition state
provides the fundamental mechanism for breaking up the hydrogen bonding strength
in the catalysis of H2O2 using the Au− ion.132 It is important to note that the Au− ion is
employed here as a prototype for negatively charged gold clusters or surfaces. The
relatively large binding energy associated with the Au− ion is of fundamental
significance as compared to that of the Au+ ion or the neutral Au atom. Contrary to
bulk gold, nanogold exhibits surprisingly high activity and/or selectivity in the
combustion as well as partial oxidation of various molecules and compounds.133 Since
the publication of the paper,133 there have been considerable research activities on
nanogold, particularly on its catalytic properties.133–143 The mechanisms of charge
transfer135,136 and relativity137 have been advanced as possible explanations for the
excellent catalytic properties of gold nanoparticles.
Recently, the negative ion resonances that characterize the electron elastic
scattering TCSs for atomic Au have been proposed as the fundamental mechanism
driving nanoscale catalysis.130,131 The catalytic combustion of methane, the main
component of natural gas, including its conversion to useful products, has recently
received extensive experimental and theoretical attention because of the potential to
reduce pollutant emissions and synthesize useful chemicals.155–160 A recent
investigation demonstrated the selective conversion of a mixture of methane and
62
oxygen to formaldehyde at temperatures below 250 K through temperature-controlled
Au2+ nanocatalysis.160 Experimentally, it has been established that the Au− anion
interacts with water molecules to form the Au− (H2O)1,2 complexes, causing bond
breaking and with methane to form the Au−(CH4) complex,161 thereby weakening the
C–H bond. Furthermore, the strong interaction between the Au− anion and H2O is
comparable to the hydrogen bonding in H2O and the Au− anion interaction with CH4 is
significant as well, but the Au− ion does not interact with O2.154 These findings154,169
are vital to the fundamental understanding of nanocatalysis using Au nanoparticles. To
our knowledge, our proposed approach is the first to use the Au− negative ion in the
catalytic combustion of methane to useful products without the emission of CO2.
4.2 Reactions and Calculation Method
The complete combustion of methane leads to the formation of carbon dioxide and
water:
CH4 + 2O2 → CO2 + 2H2O (1)
Possible by-products of the partial oxidation of methane are:
CH4 + �
� O2 → CO + 2H2 (2)
CH4 + �
� O2 → CH3OH (3)
CH4 + O2 → H2CO + H2O (4)
CH4 + O2→HCO2H + H2 (5)
63
Generally, there is little competition between the complete oxidation, reaction
(1) and the selective partial oxidation (SPO), reactions (2)-(5), of methane. There are
two reasons why the overall reaction leads to the formation of carbon dioxide and
water: (1) Complete combustion of methane occurs at the lowest temperature
compared to its SPO and (2) the corresponding transition state for reaction (1) is
lowest compared to that of any SPO of methane to the desired products. However, the
atomic Au− negative ion activates molecular oxygen in CH4 and increases the level of
the SPO of methane to produce useful compounds. Here the atomic Au− catalyst is
used to control the oxidation temperature of methane around 325 K to lower the
transition state by about 32 % compared to the case of the absence of the catalyst for
the complete oxidation of methane to methanol and further oxidize methanol to
formaldehyde and formic acid without CO2 emission. We follow exactly the same
procedure as in130,131 when applying the atomic Au− ion catalyst to each of the
reactions (1)-(5).
The proposed mechanism of catalysis using the negative Au− ion catalyst is as
follows. When a slow electron collides elastically with a ground-state neutral gold
atom, attachment can result, leading to the formation of a negative ion resonance due
to the formation of compound atomic states. The energy position of this negative ion
resonance corresponds to the stable bound state of the Au− negative ion formed during
the collision as a resonance. The binding energy of the Au− ion defines the EA of
atomic Au. Theoretically, it has been demonstrated that the EA of Au is right at the
64
absolute minimum or the second R-T minimum (absolute) of the elastic TCS of Au.130,
131,162,163 At this minimum and within the appropriate environment, the attachment of
the Au− negative ion to the CH4 molecule results in the formation of the Au−(CH4)
anionic molecular complex. This complex formation results in the disruption of the
stable C–H bonds in the methane molecule. The attendant change in the Gibbs energy
of the system becomes negative, thereby thermodynamically favoring the formation of
methanol. The Au− ion is released after the chemical reaction. We note that the
dissociative energy of the Au−(CH4) molecular complex is within the second R-T
minimum of the Au elastic TCS.
We have also employed the first principles calculations based on DFT and
dispersion-corrected DFT approaches for the investigation. For geometry optimization
of structural molecular confirmation, we utilized the gradient-corrected Perdew–
Burke–Ernzerfof parameterizations164 of the exchange correlation rectified with the
dispersion corrections.161 The double numerical plus polarization basis set was
employed as implemented in the DMol3 package.166 The dispersion correction method,
coupled to suitable density functional, has been demonstrated to account for the long-
range dispersion forces with remarkable accuracy. We used a tolerance of
1.0 × 10−3 eV for energy convergence. A transition-state search employing nudged
elastic bands facilitates the evaluation of energy barriers.167–169 Finally, the energy of
the transition state and thermodynamic curves of the reactions were calculated from
the DMol3 package.166 As the calculation of the transition barrier depends crucially on
65
the exchange correlation scheme employed, the use of reliable dispersion-corrected
approach is essential. The error in extracting the transition barrier associated with the
transition pathway was estimated to be less than 0.001 eV.167–169
4.3 Results and Discussion
Figures 16-20 present the optimized structures of the reactants, transition
states, and products of oxidation of methane leading to the formation of CO2, CO,
CH3OH, H2CO, and HCO2H, respectively. The data in (a) correspond to the absence
of the Au− ion catalyst while those in (b) are data when the Au− ion catalyst is present.
The red, white, gray, and gold spheres represent respectively oxygen, hydrogen,
carbon, and gold atoms. The TS and EP, both in electron volts, represent respectively
the calculated transition-state energy and the energy of the products. The breaking of
the stable C–H bonds in the methane molecule in the transition state resulting in the
formation of methanol in the presence of O2 is attributed to the formation of the
anionic Au− (CH4) complex. The role of the Au− ion is to disrupt the stable C–H bonds
in the methane molecule, allowing the formation of methanol in the presence of O2. It
is noted that the optimized structure corresponding to the reaction (3), namely the
production of methanol, has the lowest transition-state energy (see Figures. 16(b)-
20(b)). These results are also summarized in Table 4.
Figure 16. Complete oxidation of methane to carbon dioxide and water in the absence (a) and presence (b) of the Auspheres represent respectively oxygen, hydrogen, carbon, and gold atoms.
Figure 17. Oxidation of methane to carbon monoxide and hydrogen gas in the absence (a) and presence (b) of the Auspheres represent respectively oxygen, hydrogen, carbon, and gold atoms.
( )
Complete oxidation of methane to carbon dioxide and water in the absence and presence (b) of the Au− negative ion catalyst. The red, white, gray, and gold
spheres represent respectively oxygen, hydrogen, carbon, and gold atoms.
Oxidation of methane to carbon monoxide and hydrogen gas in the absence and presence (b) of the Au− negative ion catalyst. The red, white, gray, and gold
spheres represent respectively oxygen, hydrogen, carbon, and gold atoms.
( )
66
Complete oxidation of methane to carbon dioxide and water in the absence negative ion catalyst. The red, white, gray, and gold
spheres represent respectively oxygen, hydrogen, carbon, and gold atoms.
Oxidation of methane to carbon monoxide and hydrogen gas in the absence negative ion catalyst. The red, white, gray, and gold
spheres represent respectively oxygen, hydrogen, carbon, and gold atoms.
Figure 18. Oxidation of methane to methanol in the absence (a) and presence (b) of the Au− negative ion catalyst. The red, white, gray, and gold spheres represent respectively oxygen, hydrogen, carbon, and gold atoms.
Figure 19. Oxidation of methane to formaldehyde and water in the absence (a) and presence (b) of the Au− represent respectively oxygen, hydrogen, carbon, and gold atoms.
Oxidation of methane to methanol in the absence (a) and presence (b) of the negative ion catalyst. The red, white, gray, and gold spheres represent
respectively oxygen, hydrogen, carbon, and gold atoms.
Oxidation of methane to formaldehyde and water in the absence (a) and negative ion catalyst. The red, white, gray, and gold spheres
represent respectively oxygen, hydrogen, carbon, and gold atoms.
67
Oxidation of methane to methanol in the absence (a) and presence (b) of the negative ion catalyst. The red, white, gray, and gold spheres represent
Oxidation of methane to formaldehyde and water in the absence (a) and negative ion catalyst. The red, white, gray, and gold spheres
Figure 20. Oxidation of methaand presence (b) of the Auspheres represent respectively oxygen, hydrogen, carbon, and gold atoms.
TS, EP, and T represent, respectively,products and temperature of the reaction.
CH4 + 2O2→CO2 + 2H2O
CH4 + O2→CO + 2H2
CH4 + O2→CH3OH
CH4 + O2→H2CO + H2O
CH4 + O2→HCO2H + H2
Oxidation of methane to formic acid and hydrogen gas in the absence (a) Au− negative ion catalyst. The red, white, gray, and gold
spheres represent respectively oxygen, hydrogen, carbon, and gold atoms.
Table 4
TS, EP, and T represent, respectively, the calculated transition state, energy of the products and temperature of the reaction.
TS (eV) EP (eV) T(K) TS (eV) EP (eV)
No
catalyst
No
catalyst G�=�0
Catalyst
Au−
Catalyst
Au
3.21 −1.23 340 3.22 −1.21
4.47 −1.61 500 3.51 −1.60
4.41 −1.56 475 3.01 −1.56
4.24 −1.42 450 3.29 −1.43 3.98 −1.33 425 3.71 −1.34
68
ne to formic acid and hydrogen gas in the absence (a) negative ion catalyst. The red, white, gray, and gold
spheres represent respectively oxygen, hydrogen, carbon, and gold atoms.
the calculated transition state, energy of the
EP (eV) T(K)
Catalyst
Au−
G�=�0
−1.21 340
−1.60 375
−1.56 325
−1.43 350 −1.34 400
69
4.4 Understanding the Results
Here we discuss the results of the complete oxidation of CH4, reaction (1), and
of the SPO of CH4, reaction (3) as illustrations; the latter analysis also applies to the
remaining reactions. In130,131 we explained the catalytic production of H2O2 from H2O,
using the atomic Au− ion catalyst, in the presence of O2. Similarly, here we first apply
the atomic Au− ion catalyst to the complete oxidation of CH4, reaction (1), and obtain:
Au− (CH4) + 2O2→Au−+2H2O2 + CO2 (6) Au− + 2CH4 + 2O2→Au− (CH4) + 2H2O2 + CO2 (7) Adding the reactions (6) and (7), we get: CH4 + 2O2→2H2O + CO2 (8)
The Au− ion catalyst has changed nothing in the reaction, demonstrating
complete combustion. The results of Table 4 (same TS values for the absence and
presence of the catalyst) and Figures.16 and 20 are illustrations of the complete
combustion process. We note that the purpose of a catalyst is to decrease the reaction
temperature to ambient temperature.170 So, the Au− catalyst cannot be effective since
the 340 K temperature (Table 1) is the ambient temperature for CO2 production.
Next we apply the Au− ion catalyst to the reaction (3) and obtain:
Au− (CH4) + �
�O2→Au− + CH3OH (9)
70
Au− + 2CH4 + �
�O2→Au− (CH4) + CH3OH (10)
Adding the reactions (9) and (10), we have: CH4 +
�
�O2→CH3OH (11)
Contrary to the complete oxidation of methane, reaction (1), the Au− ion
catalyzes the SPO of CH4 to a new product, namely CH3OH without CO2 emission,
reaction (11). As seen from comparing the TSs in column 2 and column 5 of Table 4,
the complete oxidation leaves the TS virtually unchanged when the Au− ion catalyst is
introduced. However, for the case of the SPO of CH4, reaction (3), the TSs are 4.41
and 3.01 eV in the absence and presence of the Au− ion catalyst, respectively. So, no
barrier reduction is a manifestation of the complete oxidation of CH4. For this case the
catalyst has no effect on reaction (1). The obtained results in Table 4 and Figures 16-
20 can be understood from three perspectives: resonance scattering theory,
thermodynamics consideration, and transition-state calculations.
Specifically in Figures 21 (a) and 21 (b) we establish that the reactions
involving the production of methanol, represented by the purple curves, experience a
dramatic reduction in temperature from about 475 K to approximate 350 K due to the
addition of Au-. This a very promising result as we observed a minimization of
temperature needed for the reaction as well as methanol production without CO2
emission as represented by the black curve. There is a temperature threshold of about
50 K between methanol and CO
establishes insight for further research and development of efficie
green energy applications utilizing anionic metal systems.
Figure 21. (a) We show the region Gibbs free energy, ∆G (in electron volts) versus temperature, T (in Kelvin), in the presence of the Au− ion cat(green), and fifth (blackproduction of CH3OH, COtemperatures.(b) Change in the Gibbs free energy (in electron volts) versus temperature, T (in Kelvin), in the absence of the Ausecond (black), third (red), fourth (purplerespectively to the reactions leading to the production of COCH3OH, and CO beyond the optimum temperatures.
4.5 Resonance Scattering A
Most importantly, when a slow electron
stable negative Au− ion is formed almost exactly at the second deep R
the electron elastic scattering TCS of atomic Au.
50 K between methanol and CO2 emission when we add Au-. This is a key result that
insight for further research and development of efficient fuels and other
applications utilizing anionic metal systems.
(a) We show the region −0.50 eV ≤ ∆G ≤ 0.50 eV. Change in the ∆G (in electron volts) versus temperature, T (in Kelvin), in the ion catalyst. The first (purple), second (blue), third (red), fourth
(green), and fifth (black) curves correspond respectively to the reactions leading toOH, CO2, H2CO, CO, and HCO2H beyond the optimum
b) Change in the Gibbs free energy (in electron volts) versus temperature, T (in Kelvin), in the absence of the Au− ion catalyst. The first (blue),
ed), fourth (purple), and fifth (green) curves correspond respectively to the reactions leading to the production of CO2, HCO2H, H
OH, and CO beyond the optimum temperatures.
Scattering Approach
Most importantly, when a slow electron collides elastically with atomic Au, a
ion is formed almost exactly at the second deep R-T minimum of
tic scattering TCS of atomic Au.162,163 The binding energy of this
71
This is a key result that
nt fuels and other
0.50 eV. Change in the G (in electron volts) versus temperature, T (in Kelvin), in the
alyst. The first (purple), second (blue), third (red), fourth ) curves correspond respectively to the reactions leading to the
H beyond the optimum b) Change in the Gibbs free energy (in electron volts) versus
atalyst. The first (blue), ) curves correspond
H, H2CO,
collides elastically with atomic Au, a
T minimum of
The binding energy of this
72
atomic Au− ion has been determined experimentally to be 2.309 eV.161,171,172 This
value also corresponds to the EA of atomic Au. If CH4 is introduced at the second R-T
minimum of the electron elastic TCS of atomic Au, it attaches to the Au− ion forming
the anionic Au−(CH4) molecular complex,154,161 with the vertical detachment energy
(VDE) of 2.34 eV154 (incidentally, the R-T minimum is used in the creation of exotic
molecules such as RbCs170,174). Here we observe the remarkable characteristic of
atomic Au with respect to CH4, namely the EA of Au and the VDE of Au− (CH4) are
in the second R-T minimum of the Au elastic TCS. The interaction between the Au−
ion and CH4 is comparable to the C–H bond strength in CH4.154 Thus the Au− ion
weakens or disrupts the C–H bond in CH4 permitting the formation of CH3OH in the
presence of O2. We note that the interaction between the Au− ion and O2 is weak,154
showing the inertness of the Au− ion toward O2. After the reaction the Au− ion catalyst
is free to catalyze another reaction (the process is similar to the destruction of the
ozone by the Cl− ion). This was the determining factor in our selecting the Au− ion as
our catalyst. In154 it has been remarked that the binding energies of the corresponding
Au neutral complexes are significantly less than those of the anion species (for
example, the complex Au−(H2O) has a binding energy that is more than an order of
magnitude larger compared with that of the neutral Au(H2O) complex.154
73
4.6 Thermodynamics of Reactions
Low-energy chemical reaction dynamics provides the mechanism for making
and breaking bonds. In the CH4 catalysis to CH3OH using the atomic Au− ion, the C–H
bond breaking has been attributed to the formation of the anionic Au− (CH4) molecular
complex. The C–H bonding has a direct effect on the change in the Gibbs free energy,
G (∆G = ∆H − T∆S) where H, T, and S represent respectively the enthalpy,
temperature, and entropy. When the atomic Au− ion is introduced into the oxidation of
CH4, the breaking of the C–H bonding occurs. Therefore, the system changes from
relative order to less order. Hence, the entropy of the system increases, whereas the
enthalpy of the system decreases. The overall process results in the Gibbs free energy
being negative, resulting in the spontaneous formation of methanol. To gain a deeper
understanding of the process of atomic Au− ion catalysis, the rate of the reaction was
calculated using Arrhenius Equation.175 In Figure 16, the ∆G versus T for all the
reactions (1)-(5) is depicted. What is remarkable about the effect of the Au− ion
catalyst on the SPO of CH4 to CH3OH and the complete oxidation of CH4 is that
whereas in the absence of the Au− ion catalyst, the production of methanol is at a
much higher temperature (Table 4 and Figure 21(b)). However, the introduction of the
Au− ion catalyst into the reaction (3) dramatically impacts the rate of the reaction,
lowering the temperature at which ∆G = 0, from 475 to 325 K (Table 4 and Figure
21 (b)); this temperature is lower than that for the emission of CO2 (340 K). Indeed the
74
Au− catalyst is incredibly effective in catalyzing the conversion of CH4 to CH3OH
without the emission of CO2.
4.7 Transition-State Calculations
Figures 16(a), (b) present, respectively, in the absence and presence of the Au−
catalyst the TSs and EPs for the complete oxidation of CH4 to CO2. As already
indicated, it is seen from both the figures that the TSs in the absence and presence of
the Au− ionic catalyst are virtually the same. Also the EPs differ only slightly. These
results represent the signature of the complete combustion of CH4. Henceforth, they
will be used as the benchmark for assessing the SPO of the various reactions (1)-(5).
Figures 17(a), (b) displays the calculated TSs and EPs, in the absence and presence of
the Au− ionic catalyst, respectively, for the SPO of CH4 to CO + 2H2, reaction (2).
Without the Au− ionic catalyst, the TS is 4.47 eV (Figure 17(a), while when the Au−
ionic catalysts is present the TS drops down to 3.51 eV (Figure 17(b)). This is to be
expected since the role of the catalyst is to reduce the barrier. Figures 18(a), (b)
presents respectively the data without and with the Au− ion catalyst for the SPO of
CH4 to methane, reaction (3). The introduction of the Au− ionic catalyst drops down
the TS from 4.41 eV (Figure 19(a)) to 3.01 eV (Figure 19(b)). We note that this
dramatic reduction of the TS of the reaction (3) in the presence of the Au− ionic
catalyst to a value below that of the complete oxidation of CH4 is the main result. It
75
represents a significant accomplishment in the field of catalysis using the Au− ionic
catalyst. The EPs are the same in both Figures 19(a), (b) as expected.
The results for the SPO of CH4 to H2CO + H2O without and with the Au−
ion catalyst are plotted, respectively in Figures 20(a), (b). Just as for the reactions (2)
and (3), given in Figures 18(b) and 19(b), the Au− ionic catalyst reduces the barrier
significantly. However, the TS of 3.29 eV shown in Figure 20(b) is still slightly higher
than that of the complete oxidation of CH4, reaction (1). Perhaps, another atomic
negative ion such as Pd− or Pt−162 added to the Au− ionic catalyst could reduce further
the TS of 3.29 eV to a value significantly lower than that of the complete oxidation of
CH4. We believe that with a combination of the various atomic negative ion catalysts
(see for example the various figures in reference 162), all the reactions (2)-(5) could
be catalyzed directly as in the case of the reaction (3) without CO2 emission. This calls
for further investigations. Figures 15(a), (b) contrast the results for reaction (5), in the
absence and presence of the Au− ion catalyst, respectively. Interestingly, for this
reaction, the Au− ionic catalyst reduces the TS by a small amount, 3.98 versus 3.71
eV. As expected, the EP remains unchanged in both figures.
Comparing all the results presented in Figures 16-20, it is seen that the Au− ion
catalyst has a dramatic effect on reaction (3). Namely, it reduces the TS of the reaction
to a value below that obtained for the complete oxidation of methane. Hence, our main
focus is on reaction (3). The results of these figures are summarized in Table 1.
Figures 16(a), (b) presents the results of ∆G (in electron volts) versus T (in Kelvin) for
76
the reactions (1)-(5). Figure 16(a) represents the data in the presence of the Au− ionic
catalyst, while Figure 16(b) gives the results in the absence of the catalyst. We focus
our discussion on reactions (1) and (3), namely the complete oxidation of CH4 and the
production of methanol. Note the position of the curve for the complete oxidation of
CH4, represented by the first curve in Figure 16(b), blue, and by the second curve in
Figure 16(a), blue. In Figure 16(b), without the Au− catalyst, the production of the
methanol curve occupies the position 4, purple. However, in the presence of the Au−
catalyst, curve 4 jumps dramatically to position 1(Figure 16(a)) ahead of the CO2
production curve; the temperature at ∆G = 0 is 325 K. This can be compared with
that of the CO2 production at 340 K. Important here is that the CO2 curve does not
change its position from that it occupied in Figure 16(b). This clearly demonstrates the
considerable effect the catalyst has on the methanol production. Again this represents
the main result of this calculation. These data exhibit clearly the extent to which a
reaction has been influenced by the presence of the Au− catalyst. By controlling the
temperature around 325 K, methane can be completely oxidized to methanol, rather
than to carbon dioxide (see Figure 16(a), first graph), and methanol can further oxidize
to formaldehyde and formic acid.
77
4.8 Remarks on the Results
As seen from Table 4, the thermodynamics properties agree excellently with
the transition-state calculations of the complete and selective partial oxidation of
methane. Combustion of methane to carbon dioxide and water in the presence and
absence of the Au− ionic catalyst yields almost the same transition state. However, for
the selective partial oxidation of methane, there is a significant change in the transition
states when we compare the results in the presence and absence of the Au− ionic
catalyst. The introduction of the Au− ion catalyst lowers the transition states for the
formation of CO, CH3OH, H2CO, and HCO2H by 21, 32, 22, and 7 %, respectively.
Also when we compare the transition states in the absence of a catalyst for the
formation of carbon dioxide and methanol, we clearly see that the TS for the formation
of CO2 is smaller than that for the methanol formation. This elucidates why methane
undergoes complete oxidation to carbon dioxide, resulting in the increased pollutant
emissions. However, if the Au− ion catalyst is used, the oxidation of methane favors
the formation of methanol because its TS is lower than that of carbon dioxide. This is
much like the separation of a mixture of alcohol and water through the temperature
control. In summary, this proposed catalytic process involving the use of the atomic
Au− ionic catalyst promises a first and a giant step toward finding and assembling
nanocatalysts atom by atom for various chemical reactions, including the direct partial
oxidation of methane to useful products without CO2 emission. This will certainly
78
address the problem of greenhouse gas emissions, with considerable impact on the
environment.
4.9 Discussion of Results
Nanoparticles are essentially a small cluster of atoms; here we are dealing with
a single atom (more specifically, its negative ion). The origin of the catalytic activity
of supported gold nanoparticles is still not fully understood.176 Turner et al.176
investigated the catalytic behavior of very small size (approximately 1.4 nm) gold
nanoparticles obtained from atomic gold clusters. They speculated that the remarkable
catalytic behavior of the atomic nanoparticles was due partly to the strong electronic
interaction between the gold and the titanium dioxide support. Here we use atomic
gold and atomic gold anion, such as used in the experiment of Zheng et al.161, which
are obtained from laser-ablated gold foil. This completely avoids any complication
associated with the support. In130,131 we have used a similar analysis to understand the
experiments128,129 on the catalysis of H2O2 from H2O using Au and Pd nanoparticles.
This investigation could also help toward understanding the issue of the support since
our approach uses simply atoms and atomic anions. As pointed out in references130
and 131, our approach worked for the catalysis of H2O to H2O2 using the atomic Au−
catalyst for the reasons: the large EA of atomic Au, the presence of the second deep R-
T minimum in the electron elastic scattering TCS for atomic Au, and the existence of
the VDE for the anionic Au− (H2O) complex within this R-T minimum. For CH4
79
catalysis the first two conditions still hold. However, the VDE (2.34 eV)157 of the
anionic Au− (CH4) complex is still within this second R-T minimum of the Au elastic
TCS.
To get a sense of how the proposed mechanism might be affected when small
clusters are used rather than the atoms, we recently used density functional theory to
investigate the structure and dynamics of small clusters of 2, 3, 4, and 5 Pt atoms;173
the geometric optimization was achieved using the DMol3 package under the
generalized gradient approximation with the Perdew–Wang exchange correlation
functional.162
The electron affinities for the clusters were evaluated and compared with
measurement and other theoretical calculations. Our calculated EAs were found to be
closer to the measurement, demonstrating the importance of careful geometric
optimization of the structures. Furthermore, the EAs for the clusters did not deviate
significantly from that of the atom. This implies that the proposed mechanism would
still be applicable to small clusters. However, we do not know yet how far this would
hold as the cluster size is increased beyond 5 atoms. Importantly, Hakkinen et al.174
investigated the VDE for Au7 ; they found that the calculated VDE varied between
2.75 and 3.57 eV, with their value being 3.46 eV which agrees well with the
experimental value of 3.5 eV cited in reference 174. Even for a cluster of this size, our
analysis would work because the VDE of Au7 is still within the effective range of the
second R-T minimum of the Au elastic TCS.126,127To firm this, we would need to
80
calculate the electron elastic TCS for the Au7 cluster and identify the R-T minimum
and the various resonances.162
This will certainly be one of our future research projects. Finally, the present
paper could also lead to a better understanding of the role of the noble metal particle
(Au) size and the TiO2 polymorph in the catalytic production of H2 from ethanol.178
Notably, Au nanoparticles of size in the range 3–12 nm were found to be particularly
photo-reactive.
4.10 Conclusion
The atomic Au− ionic catalyst is found to reduce the optimum temperature for
the SPO of methane to about 325 K for CH3OH production. Consequently, in the
presence of the atomic Au− ion catalyst, by controlling the temperature around 325 K,
methane can be completely oxidized to methanol without the emission of the CO2,
thereby broadening considerably the scope of gold’s applications. Using the Au− ion
as the catalyst essentially disrupts the C–H bonding in CH4 oxidation through the ionic
Au− (CH4) molecular formation, thereby eliminating the competition from the carbon
dioxide formation. We conclude by recommending that the negative ions of the atoms
such as those in162 be investigated individually or in combinations for possible
catalytic activities in the selective partial oxidation of methane; the Pt− negative ion
will accomplish similar results as the Au− ionic catalyst.
81
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