Preface
Page: ii-ii (1)
Author: Ambrish Kumar Srivastava* and Ruby Srivastava*
DOI: 10.2174/9789815274042124010002
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Atomic Clusters: An Introduction
Page: 1-24 (24)
Author: Ambrish Kumar Srivastava* and Ruby Srivastava*
DOI: 10.2174/9789815274042124010003
PDF Price: $15
Abstract
An assembly of a few to thousands of atoms or molecules is referred to as a
cluster. This chapter exclusively deals with atomic clusters and their classifications
based on the nature of bonding and the number of constituents. The size effect, surface
phenomena, and variation of properties with the size of atomic clusters have also been
discussed. The difficulties in cluster experiments have been highlighted. Various
theoretical methods to study the clusters have been mentioned, with the main focus on
the density functional theory (DFT). The accuracy of various DFT methods and
choosing appropriate methods have been particularly discussed. Finally, the way to
perform DFT-based studies on clusters is also explored. This chapter provides a brief
introduction to what the book is all about.
Structural Optimization of Atomic Clusters
Page: 25-42 (18)
Author: Ambrish Kumar Srivastava* and Ruby Srivastava*
DOI: 10.2174/9789815274042124010004
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Abstract
This chapter exclusively addresses the algorithms employed to perform
geometry optimization of clusters. These algorithms can be broadly classified into two
groups: gradients-based algorithms and gradient-free algorithms. Gradient-based
algorithms use the gradient of potential energy functions to give local minima. On the
contrary, gradient-free algorithms are inspired by natural processes, which exploit
some mathematical models, which lead to global minimum. Although there are a
variety of gradient-free algorithms, some of the most popular ones include genetic
algorithm, particle swarm, simulated annealing, etc. The strengths and weaknesses of
all these algorithms have been also discussed.
Adsorption of CO2 on Transition Metal-Doped Cu Clusters: A DFT Study
Page: 43-59 (17)
Author: Ambrish Kumar Srivastava* and Ruby Srivastava*
DOI: 10.2174/9789815274042124010005
PDF Price: $15
Abstract
Activation of CO2
is the first step towards its reduction to more useful
chemicals. Electrochemical CO2
reduction reactions can lead to high value-added
chemical and materials production while helping decrease anthropogenic CO2
emissions. In studies, it was found that copper metal clusters can reduce CO2
to more
than thirty different hydrocarbons and oxygenates, yet they lack the required
selectivity. Density functional theory (DFT)-based studies are carried out on copper
clusters, doped clusters, nano-structures and Cu-based alloy catalysts to assess the
activity and selectivity of CO2
reduction to generate carbon monoxide (CO), formic
acid (HCOOH), formaldehyde (H2C=O), methanol (CH3OH) and methane (CH4
). In
this chapter, we will discuss the effect of the adsorption of CO2
on (Sc, Ti, V) metaldoped clusters. DFT studies carried out for these clusters showed a high CO2
adsorption energy, a low activation barrier for its dissociation, and a facile regeneration
of the clusters. The reaction energies (dopant-dependent), the mechanisms for reaction,
dissociation barriers for CO2, and less desorption energies (dopant dependent) for
carbon monoxide (CO) during the activation of CO2
with Cu3X clusters (X= first row
transition metals) are discussed in the chapter. C6Li6
is not capable of capturing CO2
molecules but is effective in their storage. The interaction of CO2with superalkalis such
as FLi2
, OLi3
, and NLi4
and non-metallic superalkalis such as F2H3
, O2H5, and N2H7
is
also included due to its applications.
DFT Studies on Intermediates for Sizeable Endohedral Metallofullerenes
Page: 60-70 (11)
Author: Ambrish Kumar Srivastava* and Ruby Srivastava*
DOI: 10.2174/9789815274042124010006
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Abstract
“Endohedral metallofullerenes (EMFs)”, also known as metallofullerenes,
are the hybrid molecules of spherical nanocarbons. The structure of EMFs consists of
atomic metal(s) or metal-containing clusters enclosed inside the fullerenes. These
unique EMFs have potential applications in various fields. Smalley and coworkers first
reported the EMFs in 1985 [1], soon after C60 was discovered. In this chapter, we will
discuss the computational studies carried out for the various types of EMFs and their
potential role in industrial applications. Endohedral metallofullerenes M@C44
containing several different gap atoms of scandium and titanium family are
experimentally detected. Dispersion-corrected DFT was carried out to study C44 and its
fullerene derivatives to calculate the binding properties and interactions. Results
showed that the computational and experimental studies agreed well with C44 and its
endohedral compounds. Results predicted that C44 D2
(89) isomer is suitable for
forming endohedral compounds. The binding affinity of the endohedral atom and its
enclosure showed good profusion of these clusters. The DFT studies are used to study
different characteristics of the doped C44-D2
(89) to the tri and tetra anions of empty
C44-D2
clusters. These metal−cage bonds possess partial (ionic and covalent)
interactions. The aromaticity of the cage is estimated with nucleus-independent
chemical shift (NICS(0)), as it plays a vital role in balancing the endohedral species.
DFT Studies on Nucleic Acid Base (NAB)−M2 /M2 2+ Complexes
Page: 71-89 (19)
Author: Ambrish Kumar Srivastava* and Ruby Srivastava*
DOI: 10.2174/9789815274042124010007
PDF Price: $15
Abstract
Metal clusters, atomically precise aggregates of metal atoms, when prepared
in the gas phase, produce only “magic numbers” sizes. Small-sized metal clusters (2
nm (<~100 atoms)) have different geometric and electronic properties as compared to
bulk metal structures. Metal clusters are used as new functional nanomaterials in
various applications. In this chapter, the interactive properties of different nucleic acid
bases (NAB) with M2
/M2
2+ (M = Ag, Au, and Cu) are studied by theoretical means.
Transition metals have a great affinity toward nucleic acids, which makes them suitable
candidates for metal ion sensing, removal of toxic metal ions, and the construction of
functional metal nanostructures. The highly significant symmetric dinuclear metalmediated homo base pairs structures with significant stabilities play a vital role in
various applications. Metal-nucleobase complexes have wide applications, such as
sensors, bidirectional nucleobases, logic gates, and nanowires. A logic gate programs
cells for biomedical and environmental applications. In this chapter, the electronic and
optoelectronic properties of M2
and M2
2+ with various NAB pairs, such as
adenine−thymine (AT), adenine−uracil (AU), adenine thymine (ATAT) Watson Crick
(WCST) stacking pairs, adenine−adenine stacking pairs (AAST), and adenine−adenine
hydrogen bonding (AAHB) (M = Ag, Au, Cu), are studies, along with their
applications.
Molecular Clusters and Hydrogen Storage by Clusters of Alkaline Earth Metal Oxides
Page: 90-105 (16)
Author: Ambrish Kumar Srivastava* and Ruby Srivastava*
DOI: 10.2174/9789815274042124010008
PDF Price: $15
Abstract
This chapter is exclusively devoted to molecular clusters. Molecular clusters
refer to finite aggregates of molecules or compounds. In such clusters, molecules are
usually bound by hydrogen bonding, van der Waals, or similar weak interactions. We
have shown some examples of molecular clusters, such as the clusters of H2O and LiF
molecules. Alkaline-earth metal oxide clusters such as (BeO)N
, (MgO)N
, and (CaO)N
have specifically been discussed, and their hydrogen storage behavior have been
explored using various DFT methods such as B3LYP, PBE-D3, M06-2X, etc. B3LYP
is a hybrid functional. PBE-D3 is a dispersion-corrected GGA functional, whereas
M06-2X is a meta GGA functional, as discussed in Chapter 1. It was found that small
(BeO)N
clusters prefer planar structures due to partially covalent Be-O bonds, unlike
ionic Mg-O and Ca-O bonds. Although all these clusters can effectively adsorb H2
molecules, smaller clusters serve as better adsorbents due to the high percentage mass
ratio.
Atomic Clusters: Conclusions, Prospects and Perspectives
Page: 106-113 (8)
Author: Ambrish Kumar Srivastava* and Ruby Srivastava*
DOI: 10.2174/9789815274042124010009
PDF Price: $15
Abstract
This chapter provides a summary of the book and offers some future
perspectives.
Subject Index
Page: 114-118 (5)
Author: Ambrish Kumar Srivastava* and Ruby Srivastava*
DOI: 10.2174/9789815274042124010010
PDF Price: $15
Introduction
DFT-Based Studies On Atomic Clusters explores the structures, properties, and applications of a variety of atomic clusters using density functional theory (DFT) methods to offer a simple and comprehensive explanation of the subject. The book is organized into seven chapters. Chapter 1 introduces atomic clusters and provides a quick survey of density functional theory and its role in the study of atomic clusters. Chapter 2 discusses the optimization of atomic clusters using various algorithms. Chapters 3, 4, and 5 cover the applications of DFT methods on chemical interactions involving metal complexes and ions. Chapter 6 is devoted exclusively to molecular clusters for completeness. Chapter 7 concludes the book and provides a perspective on future directions on the subject. Theoretical and practical concepts of DFT methods of the book are systematically and concisely presented with the help of clear language. Several illustrations in the form of graphics and tables are included for the benefit of readers. This reference is intended as a guide for advanced graduate and doctorate level scholars, postdoctoral researchers, and faculty members who are required to understand the application of density functional theory for explaining the properties of atomic clusters as part of foundational coursework or supplementary reading.