Book Volume 2
Preface
Page: ii-iii (2)
Author: Paulpandian Muthu Mareeswaran and Jegathalapradhaban Rajesh
DOI: 10.2174/9789815238150124020002
PDF Price: $15
Fenton and Fenton-Like Processes for the Degradation of Dye in Aqueous Solution
Page: 1-21 (21)
Author: R. Liju and Eswaran Rajkumar*
DOI: 10.2174/9789815238150124020004
PDF Price: $15
Abstract
Water is necessary for the growth of humans and all other living things.
Water is becoming scarce due to industrialization and its rapid growth, and the water
ecosystem is negatively impacted by the direct release of wastewater into the
environment. The textile, tanning, coating, plastics, paint, printing, and other industries,
discharge dyes and pigments into the environment. One major problem is to remove
dyes and pigments from industrial wastewater in a inexpensive and environmentally
friendly way. Before they are released into the environment, there are several ways to
mitigate the situation, including chemical, biological, and chemical oxidation
processes. The advanced oxidation process (AOP) is a widely employed technique for
eliminating contaminants from water and wastewater. The dye molecules are broken
down by a Fenton and Fenton-like mechanism, in which the breakdown of hydrogen
peroxide produces hydroxyl radicals. This chapter focuses on the most current
advancements and various strategies used in the Fenton and/or Fenton-like processes
used to degrade the dye molecules.
Photocatalytic Dye Degradation Using Metal Organic Frameworks
Page: 22-53 (32)
Author: Nainamalai Devarajan and Paulpandian Muthu Mareeswaran*
DOI: 10.2174/9789815238150124020005
PDF Price: $15
Abstract
This chapter deals with degrading dyes using Metal-Organic Frameworks as
a heterogeneous catalyst. Metal-Organic Frameworks (MOFs) are an excellent material
for dye degradation due to their multifunctionalities, such as semiconducting
properties, ease of use with controllable structures, high surface area, and enormous
active sites. MOFs exhibit a promising photocatalytic activity under UV–visible light
irradiation due to band gap presence. Several MOFs show an excellent reusability
performance even after a few consecutive cycles. The MOFs used to degrade dyes are
classified as bare MOFs (Lewis acid MOF, Brønsted Base MOF), MOFs@SiO2
,
magnetic MOFs, MOF nanocomposites, ionic MOFs, bimetallic MOFs, nanoparticles
doped MOFs, etc., The mechanism of dye removal and photocatalytic degradation of
organic dyes using MOFs and the detailed pros and cons of these materials are
discussed in detail.
UV, Visible, and Near-Infrared Responsive Photocatalyst for Dye Degradation
Page: 54-76 (23)
Author: Natarajan Prakash*, Subramanian Balachandran, Muhammad Y. Bashouti, Mukkanan Arivananthan and Yasuhiro Hayakawa
DOI: 10.2174/9789815238150124020006
PDF Price: $15
Abstract
Environmental contamination has long been a big problem for the planet.
One of the greatest ways to harness the massive amounts of sunshine available is
photocatalysis, which may be used to remove dangerous organic pollutants from water
and the air. Due to its large band gap (3.2 eV), the golden standard TiO2
catalyst only
uses the UV area of the sun, or 5% of it, and cannot absorb all of the solar energy. To
attain optimal photocatalytic effectiveness, the photocatalytic materials must efficiently
harvest photons from sunlight's visible, NIR, and ultraviolet energies to form
photocarriers. Several methods for efficiently forming and separating light-induced
charge carriers and absorbing visible and near-infrared light photons from sunlight are
compiled in this chapter to provide increased photocatalytic efficiency. Effective
tactics, including doping and the fabrication of composite materials, are highlighted to
emphasize the distinct physicochemical qualities and photocatalytic enhancement of
changed materials that are impacted by band alignment, shape, and defect structures.
Despite the discussion of an up-conversion method for NIR light absorption,
multiphoton emission, continuous luminescence, photo carrier multiplication, and/or
plasmonic processes, in addition to the control of photo-thermo effects, make it
difficult to use NIR effectively. To fully use the solar spectrum for enhanced
photocatalytic pollutant degradation, the chapter provides an overview of UV, Visible,
and/or NIR active catalytic materials based on design, synthesis, and interface
engineering.
Transition Metal Dichalcogenide Hybrids for Visible-light-driven Photocatalytic Dye Degradation
Page: 77-89 (13)
Author: M. Karpuraranjith*, Y. F. Chen*, S. Rajaboopathi, R. Manigandan, K. Srinivas and SPR. Poonkodi
DOI: 10.2174/9789815238150124020007
PDF Price: $15
Abstract
The 21st century has seen tremendous industrialization in many countries
worldwide, making environmental protection and energy conversion important issues.
As such, investigations on the decomposition of dye molecules in water for
environmental protection and clean energy construction are challenging yet impressive.
It is still difficult to create a photocatalyst with a sensible design that is affordable and
extremely effective for degrading organic dye contaminants. Our work showcases an
incredibly effective “interfacial connection and suitable band gap matching” method to
create nano-architecture hybrid catalysts based on Transition metal dichalcogenides
(TMDs) built using hydrothermal processes. With its large surface area, colossal
energetic sites, and interfacial charge assignment, the TMDs-based nano-hybrid
catalyst significantly enhances the catalytic degradation of dye pollutants. This
demonstration could provide a new hybrid catalyst that degrades dye molecules more
effectively and sustainably when exposed to visible light. Lastly, certain
recommendations are emphasized for advancing hybrid catalysts based on transition
metal dichalcogenides in the future.
Photocatalytic Degradation of Dyes Using Green Synthesized Metal Nanoparticles
Page: 90-114 (25)
Author: Sheeba Daniel*
DOI: 10.2174/9789815238150124020008
PDF Price: $15
Abstract
Environmentally hazardous, synthetic organic substances with a complex
structure are known as dyes. A major environmental issue is the removal of dyes from
the environment, and many techniques are often employed to break down colors. One
thought to be a good replacement for dye degradation is photocatalysis. Various
photocatalysts carry out the complete mineralization of colors without generating
hazardous by-products. When exposed to UV or visible light, metal nanoparticles'
promising catalytic ability allows them to break down dangerous synthetic dyes.
Compared to traditional methods, green production of metal nanoparticles is more
economical and environmentally benign. This book chapter focuses on using different
green synthesized metal nanoparticles to degrade synthetic colors. The
photodegradation mechanism presented in this chapter could clarify future uses for dye
degradation.
Recent Developments and Perspectives in Photocatalytic Degradation of Dyes Employing Metal Oxide Nanoparticles
Page: 115-138 (24)
Author: Selvakumaran Nagamani*
DOI: 10.2174/9789815238150124020009
PDF Price: $15
Abstract
Among the 7×105
tonnes of synthetic dye manufacturing, 1,000 tonnes of
non-biodegradable textile dyes are disposed each year into natural streams and water
bodies. Due to rising environmental concerns and awareness, it is necessary to remove
dyes (pollutants) from municipal and industrial water effluents using a method that is
both efficient and affordable. In this regard, photocatalysis has proven to be a safe,
long-lasting, and effective wastewater treatment method with a high potential for color
removal. Due to their excellent potential as a photocatalyst to degrade various organic
dyes, metal oxide nanoparticles have been hailed as promising materials throughout the
past two decades. The fundamentals of photocatalysis, drawbacks of traditional water
purification techniques, and strategies for dye decolorization and degradation are all
briefly covered in this book chapter. It focuses on the mechanisms in relatively wellunderstood metal oxide photocatalysts. It summarizes recent developments to improve
metal oxide NPs photocatalytic efficiency, shape and structural modifications of metal
oxide, and immobilization of metal oxide by using various supports to make it a
versatile and financially successful dye treatment technology. Then, the conclusion and
the outlook for the future were considered and hypothesized, releasing the field for
advanced study to be granted for developing a photocatalytic system that can be widely
employed for various pollutants.
Graphene Oxide Nanocomposites: Photocatalytic Dye Degradation Investigations
Page: 139-155 (17)
Author: Paulraj Adwin Jose*, Murugesan Sankarganesh, Jeyaraj Dhaveethu Raja and Jegathalaprathapan Rajesh
DOI: 10.2174/9789815238150124020010
PDF Price: $15
Abstract
This chapter presents research on using novel dye-degrading processes in the
chemical process industries to prevent the increasing water demand caused by the
overuse of water in businesses near farmland. This chapter also describes the dye
degradation processes used to treat industrial effluents contaminated with dyes and the
associated chemical reactions, benefits, and drawbacks. Commonly employed chemical
techniques for treating industrial effluents contaminated with dyes demand more costly
chemicals and reagents for dye degradation. Solid precipitates or emulsions are created
when the additional chemicals interact or react with the contaminants in the industrial
effluents that are contaminated with dye. These products could harm our ecological
creatures in a variety of ways. Physiological techniques like membrane filtration, nanofiltration, ultrafiltration, and microfiltration have their membrane pores closed by
different pollutants, shortening their lifespan. The primary focus of this chapter is on
the dye degradation characteristics of graphene oxide nanocomposite materials that
have been mixed or doped with different metal oxides and metal nanoparticles. These
days, there is increased interest in carbon-based compounds such as graphene and
graphene oxides due to their potential environmental benefits when used in the oil and
organic gas industry to purify water. The water purification activity of graphene oxide
filters is further increased when combined with photochemical active metal oxide.
Another benefit is that they don't require extra chemicals or reagents, which also
indirectly control other pollutants, and they use solar energy rather than electrical
energy. These graphene oxide nanocomposites are unique because they can regenerate
without chemicals once they run out of resources. Its physical and chemical
characteristics don't change over many cycles.
Subject Index
Page: 156-161 (6)
Author: Paulpandian Muthu Mareeswaran and Jegathalapradhaban Rajesh
DOI: 10.2174/9789815238150124020011
PDF Price: $15
Introduction
This series provides information on the nature of dyes, their harmful effects, and dye degrading techniques. The second volume focuses on sophisticated oxidation methods for dye degradation. The information on target-oriented dye mitigation is intended to give readers a better understanding of the dye degradation process to sustain a healthy environment. Chapters present referenced information and highlight novel industry breakthroughs. Key topics: The Fenton process for dye removal MOF-based and graphene oxide photocatalysts for dye degradation Novel photocatalysts active in visible light and IR spectra Photocatalytic degradation of transition metal dichalcogenides Environment friendly synthesis of photocatalysts for dye degradation Metal oxide Nanomaterials for dye degradation This volume is a comprehensive singular resource on photocatalytic dye degradation for researchers, apprentices and learners in chemistry and chemical engineering courses. It also serves as a reference for industry professionals who work with chemical dyes (for example in textile and plastic industries) and are engaged in the critical field of environmental remediation.