Preface
Page: ii-iii (2)
Author: Kulvinder Singh and Vineet Kumar
DOI: 10.2174/9789815136265123010002
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Introduction to Carbonaceous Quantum Dots
Page: 1-19 (19)
Author: Abhinay Thakur, Ashish Kumar* and Sumayah Bashir
DOI: 10.2174/9789815136265123010004
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Abstract
Carbonaceous quantum dots (CQDs), relatively small carbon nanoparticles
(<10 nm in size), have sparked the attention over the last few decades for their potential
as a promising resource in various fields, such as biomedical, solar cells, sensors, water
treatment, energy generation storage because of their benign, abundant, low preparation
costs, small size, non-hazardous nature, high biocompatibility, high water solubility
and effective alteration nature. Numerous applications in optronics, catalysis, and
sensing are made possible by the excellent electronic characteristics of CQDs as
electron acceptors and donors that cause photocatalytic activity and electrochemical
luminosity. This feature series aims to assess the current status of CQDs by discussing
the literature in this field and deliberate the basics, applicability and advancements in
the field of CQDs in both scientific and technology circles.
Synthesis of Carbonaceous Quantum Dots
Page: 20-37 (18)
Author: Munish Kumar*
DOI: 10.2174/9789815136265123010005
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Abstract
New class of nanocarbon materials, such as luminescent carbon quantum
dots (CQDs) has gained a great deal of interest in the area of electrocatalysis, solar
cells, bioimaging nanomedicine, a chemical sensor and a light-emitting diode. CQDs
exhibit good physio-chemical properties, such as photoluminescence, high
crystallization and good dispersibility. The rapid electron transfer, small size and
superconductivity of CQDs provide the CQDs-based composite offering enhanced
catalytic activity and electric conductivity. However, additional active moieties are
present on the surface, which might aid in the formation of multi-component
electrically activated catalysts. Additionally, the multi-component catalysts' internal
interactions promote charge transfer and catalytic efficiency, both of which are
essential for electrochemistry. Therefore, keeping in mind the importance of CQDs,
they are synthesized on the basis of two approaches: Top-down and Bottom-up. The
bulk material is reduced in size by utilizing chemical and physical processes in the top-down approach. On the contrary, in the bottom-up method, the atoms are assembled
and converted into CQDs using polymerization and carbonization through a chemical
reaction. Hence, in this chapter, we will discuss the synthesis techniques for CQDs,
such as hydrothermal/solvothermal method, laser ablation, arc-discharge method,
acidic oxidation, thermal/combustion routes, electrochemical method and microwave
pyrolysis method.
Properties of Carbonaceous Quantum Dots
Page: 38-52 (15)
Author: Devika Vashisht, Priyanka, Aseem Vashisht, Shweta Sharma and Surinder Kumar Mehta*
DOI: 10.2174/9789815136265123010006
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Abstract
Carbonaceous quantum dots (CQDs) is defined as a subclass of carbon
nanoparticles, which offer a size of around 10 nm, and have unique characteristics and
a wide range of applications in diverse fields. CQDs have attained widespread attention
due to their excellent abilities in several domains, including sensing, nanomedicine and
environmental remediation. The mode of synthesis for CQDs is quite simple and
inexpensive via methods such as microwave pyrolysis, arc-discharge, etc. CQDs are
entitled to diverse physical, chemical and biological properties. Besides this, CQDs
have various functional groups present on their surface that improve the properties,
specifically the catalytic performance by a phenomenon called charge transfer. The
physical, optical, electrical, and biological features of CQDs are explored in this
chapter.
Characterization of Carbonaceous Quantum Dots
Page: 53-77 (25)
Author: Abhinay Thakur, Harpreet Kaur, Ashish Kumar* and Sumayah Bashir
DOI: 10.2174/9789815136265123010007
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Abstract
Carbonaceous quantum dots (CQDs), a prominent figure of carbon
materials, offer remarkable impetus in a variety of sectors, including biosensors,
biomedical imaging, drug delivery, photonics, photovoltaics, and electrocatalysis, due
to their distinctive physicochemical, optical, and electrical capabilities. This chapter
attempts to show current advances in CQD characterization, with an emphasis on the
essential multifarious function of CQDs using various techniques, such as
photoluminescence and fluorescence emission spectroscopy. Additionally, with the aim
of developing highly efficient and long-term sustainable CQD-based components, we
explore the obstacles and potential directions of CQD-based substances in this
developing research field.
Application of Carbonaceous Quantum Dots in Biomedical
Page: 78-93 (16)
Author: Yarima S. García*
DOI: 10.2174/9789815136265123010008
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Abstract
Numerous research fields, including chemistry, electronics, and medical
sciences, have concentrated on the production and use of novel functional
nanomaterials. Carbon, a component of all organic life forms, is essential for the
creation of nanomaterials. The modern carbon-based family component known as
carbonaceous quantum dots (CQD) was unintentionally discovered in 2004 while
single-walled carbon nanotubes were being purified. Additionally, CQDs have
exceptional qualities like outstanding photoluminescence and minimal toxic effects.
Outstanding in vitro andin vivo biomedical implications of CQDs include drug/gene
delivery, biosensor biotherapy, and theragnostic evolution. Also, CQDs can pass
through specific body sites of endothelial inflammation (epithelium of the intestinal
tract, liver, for example), tumors or penetrate capillaries due to their small size. For the
same reason, nanoparticles are more suitable for intravenous administration than
microparticles and also prevent particle aggregation and bypass emboli or thrombi
formation. This chapter describes the most contemporary applications of CQDs in
diverse biomedical fields. We hope it will provide incalculable insights to inspire
discoveries on CQD and delineate a road map toward a broader range of bio
applications.
Application of Carbonaceous Quantum Dots in Solar Cells
Page: 94-109 (16)
Author: Ekta Sharma* and Vaishali Thakur
DOI: 10.2174/9789815136265123010009
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Abstract
Carbonaceous Quantum Dots (CQDs) are gaining the interest of various
research groups owing to their significant features, including water stability,
biocompatibility, minimal cytotoxicity, chemical inertness and fluorescence which
make them a good candidate in solar cells applications such as photocatalysis, solar
energy conversion, photovoltaic solar cells, and Photoelectrochemical cells. CQDs are
used in photocatalytic reactions because they can be used as electron sinks to stop the
coupling of electron void pairs. The high coefficient of absorption and the broad
spectrum of absorption improve the photocatalytic activity. In solar cells, the CQDs are
used as sensitizers. CQDs are employed in solar energy generation because they are
non-toxic and affordable. This chapter discusses the use of CQDs in solar cells.
Carbonaceous Quantum Dots as Efficient Zero-dimensional Nanomaterials for Sensing Applications
Page: 110-143 (34)
Author: Alma Mejri*, Abdelmoneim Mars and Hamza Elfil
DOI: 10.2174/9789815136265123010010
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Abstract
Carbonaceous quantum dots (QDs), including carbon and graphene quantum
dots, have been widely used recently in various sensing fields, such as healthcare
sensing, environmental monitoring, and food safety. Owing to their exceptional
electronic, fluorescent, photoluminescent, chemiluminescent, and electrochemiluminescent properties, carbonaceous QDs are essential tools for designing an ultra-sensitive sensing platform. In this chapter, we summarized the applications of
carbonaceous QDs in the detection of various target analysts, citing heavy metals, toxic
compounds, pesticides, and proteins (DNA, aptamer, and RNA). In this regard, the
authors described the effects of synthetic methods and surface functionalization on the
properties of carbonaceous QDs and the analytical performance of sensors. We believe
that understanding these parameters gives us better sensors that could not be obtained
by other means. To give the reader a clear vision of the implementation of these zero-dimensional nanomaterials in sensor architectures, a comparative study has been
developed.
Application of Quantum Dots in Wastewaters Treatment
Page: 144-177 (34)
Author: Atma Rai, Garima Kumari, Eder Lima, Mika Sillanpaa, Nitesh Kumar, Anupam Guleria, Dinesh Kumar and Ashish Guleria*
DOI: 10.2174/9789815136265123010011
PDF Price: $15
Abstract
Water stress and scarcity are among the primary issue that the world is
witnessing in this era, as pollution of freshwater resources are increasing due to various
emerging pollutants, such as pharmaceuticals, personal care products, pesticides, and
household and industrial chemicals. Efficient treatment of wastewater is an important
aspect of fresh water supply, and such water can also be used for different household
activities and other purposes. So for wastewater treatment, different eco-friendly as
well as economic approaches have been analyzed, and the use of carbon quantum dots
(CQDs) for the treatment of wastewater is efficient and effective technique extensively
studied in the last few years. CQDs are promising nanomaterials for water pollution
treatment due to their small particle sizes, tuneable fluorescent properties and
containing oxygen-based functional groups. In this chapter, the chemical and physical
attributes of CQDs, raw substances and methodologies being utilized in the synthesis,
and stability of CQDs, along with their effective employment in wastewater
remediation and treatment, has discussed in detail.
Application of Carbonaceous Quantum dots in Energy Storage
Page: 178-191 (14)
Author: Vaishali Thakur* and Ekta Sharma
DOI: 10.2174/9789815136265123010012
PDF Price: $15
Abstract
Carbon quantum dots (CQDs) are a type of carbon nanomaterial that has
lately received attention as a potential replacement for standard semiconductor
quantum dots (QDs). CQDs feature a quasi-spherical structure and amorphous to
nanocrystalline carbon cores with diameters of 10-20 nm. Based on the carbon core,
CQDs are further classified as graphene quantum dots (GQDs), carbon nanodots
(CNDs), and polymer dots (PDs). CQDs exhibit unique electrical and optical properties
due to their bigger edge effects and quantum confinement; better than graphene oxide
nanosheets, they can also be easily split into electrons and holes due to their high
dielectric constant and extinction coefficient. CQDs are crucial in the sector of energy
storage and transformation because CQDs offer the advantageous properties of low
toxicity, environmental friendliness, low cost, photostability, favourable charge transfer
with increased electronic conductivity, and comparably simple synthesis processes.
Due to their superior crystal structure and surface properties, CQD nanocomposites
often helped to shorten charge transfer paths and maintain electrode material cycle
stability. CQDs provide cost-effective and environmentally friendly nanocomposites
used for supplying high energy density and stable electrodes for energy storage
applications. This chapter provides a summary of the role that CQDs play in energy
transmit technologies, including solar cells, supercapacitors, lithium-ion batteries, and
hydrogen and oxygen evolution reactions.
Future Prospect of Carbonaceous Quantum Dots
Page: 192-203 (12)
Author: Devika Vashisht, Aseem Vashisht, Shweta Sharma and Surinder Kumar Mehta*
DOI: 10.2174/9789815136265123010013
PDF Price: $15
Abstract
Carbonaceous quantum dots (CQDs) are carbon nanomaterials offering
significant contributions in the fields of sensing, biosensing, optoelectronics, and
energy storage. CQDs materials with edge defects are suitable candidates for LED
emitters, water splitting, optoelectronic and photodetectors devices. The role of
attached functional groups and edge effects on flexible energy storage devices is
discussed in this chapter. The future prospects and underlying challenges for CQD-based material for wastewater remediation, in addition to factors such as their
sustainability, durability, performance and economics in the context of industrial scale-up, have also been explored in this chapter
Subject Index
Page: 204-209 (6)
Author: Kulvinder Singh and Vineet Kumar
DOI: 10.2174/9789815136265123010014
PDF Price: $15
Introduction
This reference is a comprehensive guide to carbon quantum/ dots (CQDs) for researchers. The book includes ten chapters that explain the synthesis of CQDs, their chemical properties and their application in the field of nanotechnology. The content starts with a detailed introduction to CQDs, followed by the synthesis, chemical properties, and characterization of quantum dots. Subsequent chapters cover CQD application in the fabrication of biomedical materials, chemical sensing, wastewater treatment, toxicology, and energy storage. The final chapter of the book explores the future prospects of these quantum dots which gives a glimpse of new horizons in research and development. This book provides guidance to students and researchers who require an understanding of carbonaceous quantum dots. It also serves as a handbook for professionals, researchers and students working in chemical technology sectors.