Book Volume 2
Preface
Page: i-i (1)
Author: Goutam Kumar Patra and Santosh Singh Thakur
DOI: 10.2174/9789815079036123020001
Recent Advances in Electrocatalysis
Page: 1-32 (32)
Author: Goutam Kumar Patra*, Amit Kumar Manna, Meman Sahu, Vanshika Sharma and Santosh Singh Thakur
DOI: 10.2174/9789815079036123020003
PDF Price: $15
Abstract
In this chapter, we have briefly studied electrocatalysis. Electrocatalysis
plays an important role in many synthetic procedures, such as biodiesel production,
CO2
reduction, O2 evolution reaction, etc. Numerous electrocatalytic kinetic
characteristics are discussed to fairly assess the efficiency of electrocatalysts, including
overpotential (η), exchange current density (i0
) and Tafel slope (b). These variables are
essential and provide valuable insight into the electrochemical reaction's process. Due
to this, herein, we give a brief overview of these kinetic characteristics along with a
review of different electrocatalysts for various reactions.
Nano-Catalysis in the Selective Oxidation of Alcohols and Anilines
Page: 33-58 (26)
Author: Ashok Raj Patel, Geetika Patel, Arti Srivastava, Bhaskar Sharma, Goutam Kumar Patra and Subhash Banerjee*
DOI: 10.2174/9789815079036123020004
PDF Price: $15
Abstract
Micellar Catalyst
Page: 59-91 (33)
Author: Hitesh K. Dewangan, Neha Kandpal, Rekha Nagwanshi, Kallol K Ghosh and Manmohan L. Satnami*
DOI: 10.2174/9789815079036123020005
PDF Price: $15
Abstract
Self-aggregates microenvironment affords a robust platform for synthesizing
conventional and novel materials in aqueous media. Consequential enhanced the rate of
reaction and reduced the barrier for organic solvents. A solvent is frequently asked to
perform multiple tasks at once, such as ensuring contacts between substrates with
different polarities, controlling heat transmission, and promoting the interaction that
results in the ultimate transformation. Nature has chosen water as a solvent to carry out
all types of chemical transformations, regardless of whether the substrates are soluble
or not. Of course, surfactants resolve the various problems that arise from the
interaction of insoluble substrates and reagents. The use of surfactants under micellar
conditions represents one of the largest methods to achieve catalysis in water. To date,
micellar systems are present in many areas, e.g., medical science, nanoscience,
organochemistry and industries of their vast application.
We explained the role of micelles and vesicles on the reactivity of nucleophiles towards
the cleavage of the organophosphorus compounds. Recent developments includeapplication of micellar catalysis to complex single-phase and multiphase systems in
which the surfactant plays multiple roles and interphase transport effects are often
important. The distribution of the reagents between the aqueous phase and the micellar
phase was described in terms of a simple pseudo-phase model (PPM). These
quantitative treatments for the catalytic action of anionic reactants and the cationic
micelles for cleaving the phosphate and thiophosphate ester improved an understanding
of competitive counterion binding, the effects of reactive and inert solubilizates,
functionalized surfactants, and the use of surfactant aggregates as reaction templates.
Nanomagnetic Oxide: A Versatile Green Catalyst
Page: 92-118 (27)
Author: Sunil Kumar Singh*, Bhaskar Sharma, Arti Kumar Shrivastava and Chandni Singh
DOI: 10.2174/9789815079036123020006
PDF Price: $15
Abstract
In recent years, attempts to follow green protocol in organic synthesis have
emerged along with the use of green solvent, solvent-free reaction conditions, the
concept of multicomponent reactions and use of green catalysts. Fe3O4
is an oxide of
iron called magnetite mineral; it is a ferromagnetic and strongly magnetic mineral on
earth. It was the first mineral structure that was applied in X-ray. It is found that the
nanomagnetic oxide shows an inverse spinel structure. Its unique properties, such as
high Curie temperature, high spin polarization, and verwey transition, gains attention
towards it. Nano-magnetic oxide is employed as a green catalyst. It can be synthesized
by physical methods, microbial methods and wet chemical preparation methods. It
demonstrates excellent catalysis in organic synthesis that gives a good yield; it enjoys
an advantage over other catalysts as it is easily separable from the reaction mixtures
using a bar magnet, and it is green & eco-friendly. It also shows wide applications in
various fields, such as water treatment, biodiesel production, lithium-ion battery, and
the biomedical field.
Advantages of Nanocatalysts on Knoevenagel Condensation
Page: 119-139 (21)
Author: Mithun Kumar Ghosh and Tanmay Kumar Ghorai*
DOI: 10.2174/9789815079036123020007
PDF Price: $15
Abstract
Nanocatalysts revolutionize organic chemistry for the conversion of various
organic reactions to obtain a high yield, low hazard and stability. It plays an important
role in the transformation of organic reactions due to its high surface area, small size,
and low reaction time. Therefore, green methodology, both in the synthesis of
nanocatalysts and organic transformation reactions, is an advanced technology, and
findings promise results. Many scientists all over the world synthesised nanoparticles
and used them as catalysts in Knoevenagel condensation. In this book chapter, we
documented the synthesis and characterisation techniques of the homo/hetero metallic
nanocatalyst and applied it in the Knoevenagel condensation reaction for its reusability
and easy separation after a chemical reaction because, in organic chemistry, separation
is a tedious job for finding pure compounds.
Noble Metal Supported Heterogeneous Catalyst for Oxidation and Oligomerization Reaction
Page: 140-169 (30)
Author: Vishnu Prasad Yadav*, Anil Kumar Chandrakar and Amit Jain
DOI: 10.2174/9789815079036123020008
PDF Price: $15
Abstract
Noble metals like platinum, gold, silver, rhodium, palladium and copper
were used as catalysts and promoters in oligomerization hydrogenation,
dehydrogenation, and oxidation reaction to get valuable chemicals, and green fuel
without any harmful effect on the environment. Platinum, rhodium, palladium, copper,
monometallic and bimetallic with reducible and non-reducible supported material
zeolites, Si/Al, MCM-41 and Al2O3
show excellent activity toward conversion of
reactants. Among noble metals, gold has shown low activity and high deactivation. The
C4
hydrocarbon formation was faster than C6
during the oligomerization reaction over
the metal catalyst at mild reaction conditions.
Heterogeneous Catalysts for Photo-Oxidation
Page: 170-192 (23)
Author: Alpa Shrivastava, Dilip Raj Shrivastava and Ajaya Kumar Singh*
DOI: 10.2174/9789815079036123020009
PDF Price: $15
Abstract
Photocatalysis is gaining momentum for the degradation of persistent
pollutants apart from other applications, including wide-scale industrial use. Non-Hazardous, efficient, greener approach and reusable properties make photocatalyst
potential molecules for field application. Heterogenous make available solid surface,
absorb photoenergy and initiate redox process for target molecules. Modification of
heterogenous catalysis and improvement of the process is continuously accessed for
better performance. The current chapter deals with some important practical aspects
and challenges with some important heterogeneous catalysts like TiO2
, ZnO, CdS,etc.
Subject Index
Page: 193-194 (2)
Author: Goutam Kumar Patra and Santosh Singh Thakur
DOI: 10.2174/9789815079036123020010
Introduction
Diverse Strategies for Catalytic Reactions is a compelling exploration of catalysis, a cornerstone in chemical sciences that has propelled the evolution of chemical manufacturing at the industrial scale. Highlighting the distinctive characteristics of catalysis, the book delves into pivotal topics and subfields. It underscores the revolutionary role catalysis plays in novel design, synthesis, and energy-efficient development, while minimizing side products, promoting atom economy, and embracing green chemistry principles. The comprehensive contents of this book include an array of chapters by experts, each addressing a specific catalytic approach, such as recent advances in electrocatalysis, nano-catalysis for selective oxidation, micellar catalysis, green catalysts, and more. Each of the 7 book chapters includes a summary and list of references for a broad range of readers. Readers will understand the range of chemical engineering strategies that are used to speed up reactions and synthesize molecules of interest. With its rich insights and practical applications, this book serves as an invaluable reference for graduate students, researchers, and professionals across academic and industrial domains.