Hydrotalcite and Hydrotalcite-Based Materials
Page: 1-16 (16)
Author:
DOI: 10.2174/9789815256116124010003
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Abstract
This chapter deals with the history of hydrotalcite and hydrotalcite-based
materials. A rare mineral known as hydrotalcite was found in Sweden sometimes in the
1840s. Magnesium aluminum hydroxycarbonate, Mg6Al2
(OH)16CO34H2O, is its
chemical name, and Taylor and Allmann independently determined its layered
structure. For a long time, hydrotalcite and other isomorphous minerals (such as
piroaurite, sjogrenite, and takovite) were the focus of most mineralogical studies.
However, beginning in the 1970s, it was discovered that these rare minerals, also
known as anionic clays, could be prepared quickly and affordably in a laboratory and
have a variety of intriguing chemical properties. The different arrangements of the
stacking of the layers, the ordering of the metal cations, as well as the arrangement of
anions and water molecules in the interlayer galleries, result in a variety of
stoichiometry in hydrotalcite, which are layered double hydroxides. Due to their unique
characteristics, including their enormous surface area, ion exchangeability, insolubility
in water, and most organic sorbents, among others, the compounds of the hydrotalcite
group demonstrate a wide variety of potential uses.
Synthesis and Characterization of Hydrotalcite Based materials
Page: 17-47 (31)
Author:
DOI: 10.2174/9789815256116124010004
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Abstract
Hydrotalcite (HT) has the chemical formula Mg6Al2
(OH)16CO3
•4H2O, with a
stacked crystal structure comprising layers of positively charged hydroxides that are
interlayer anion neutralization as carbonate and contain H2O particles. These double
hydroxides in layers (LDH) are a class of highly fascinating materials for the industry
due to the simplicity of their production and the ability to add additional layer cations
and interlayer anions. Hydrotalcite-based materials such as magnesium aluminide
(MgAl) hydrotalcite with a range of magnesium to aluminium (Mg/Al) molar ratios are
used to prepare catalysts for effective changes of organic molecules. X-ray diffraction
and scanning electron microscopy (SEM) characterization measure the catalyst's
crystallinity, surface area, and shape. The HT has been employed as a scaffold for
immobilizing numerous metals, enabling highly selective organic reactions, i.e., the
dehydrogenation of alcohols and the deoxygenation of epoxides. It may also work with
other metal catalysts to speed up subsequent responses in a single pot. It offers a vital
method for the environmentally responsible synthesis of valuable compounds. This
chapter overviews the hydrotalcite synthesis, classification, and application research.
Divergent Applications of Hydrotalcite-Based Materials
Page: 48-83 (36)
Author:
DOI: 10.2174/9789815256116124010005
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Abstract
Hydrotalcites (HDTL) are layered double hydroxides of the anionic clay
family. They possess a large surface area, ability to accommodate divalent and trivalent
metallic ions, anion exchange capacity and intercalation ability. HDTL play a vital role
in nanotechnology, specifically in various nanomaterial production, functionalization,
and applications. HDTL nanohybrids with unique properties are created through
intercalation with various compounds like inorganic anions, organic anions,
biomolecules, active pharmaceutical ingredients, and dyes. Their adaptive layered
charge density and chemical combination constitute HDTL as resourceful materials
befitting for a broad spectrum of applications. There are a variety of methods for
preparing HDTL based nanomaterials, including co-precipitation, sol gel method, ion
exchange method, intercalation method and microwave assisted methods. The
morphologies of HDTL materials are characterised using technologies like X-ray
powder diffraction (XRD), Fourier Transform Infrared Spectroscopy (FTIR),
Thermogravimetry coupled (TGA) with Differential Scanning Calorimetry (DSC),
Scanning Electron Microscopy (SEM), and Transmission Electron Microscopy (TEM).
The nanocomposites of HDTL are widely used in the field of fine chemical synthesis,
pharmaceutical field, water purification, and agriculture. Biocompatible HDTL
nanostructures enticed remarkable attention in therapeutic and diagnostic functions.
HDTL nanohybrids are prominent bio reservoirs for drug and delivery systems and
used in cancer therapy. These materials have been utilised by bioimaging techniques
such as MRI and CT. The HDTL-based nanomaterials are effective adsorbents and find
widespread application in the water treatment industry. These are used for the
amelioration of polluted water by removing heavy metals, dyes, and other impurities.
These materials are also used as flame retardants, in porous ceramics, carbon dioxide
adsorption and deodorants. This chapter describes in detail about the preparation
methods, properties, structural characterisation, and wide applications of HDTL based
nanohybrids.
Hydrotalcite-Based Materials In Nanotechnology
Page: 84-106 (23)
Author:
DOI: 10.2174/9789815256116124010006
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Abstract
This book chapter focuses on the use of hydrotalcite-based materials in
nanotechnology. Hydrotalcites are layered double hydroxides with unique structures
and properties that make them attractive for various applications in nanotechnology.
The chapter provides an overview of the synthesis, characterization, and applications of
hydrotalcite-based materials in various fields of nanotechnology, including catalysis,
drug delivery, sensing, and environmental remediation. The chapter also discusses the
potential challenges and future directions in the field of hydrotalcite-based
nanotechnology. Overall, this chapter highlights the importance of hydrotalcite-based
materials as promising candidates for developing advanced nanotechnological
applications.
Industrial Application of Hydrotalcite-Based Materials
Page: 107-186 (80)
Author:
DOI: 10.2174/9789815256116124010007
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Abstract
Hydrotalcite is a layered double hydroxide (LDH) with a wide range of
applications in catalysis, flame retardancy, PVC stabilization, fillers and
reinforcements, additives in coatings and paints, pharmaceuticals and personal care,
environmental remediation, and other industrial applications. This paper provides an
overview of the properties and characteristics of hydrotalcite, as well as its potential
applications in various industries.
The paper begins with an introduction to hydrotalcite, including its definition,
structure, synthesis methods, and properties. The next section discusses the role of
hydrotalcite as a catalyst, as well as its applications in the petrochemical industry and
environmental remediation. The following section focuses on the flame retardant and
smoke suppression properties of hydrotalcite, and its applications in plastics and
polymers. The subsequent section discusses the use of hydrotalcite as a PVC stabilizer
and its benefits and applications in the PVC industry.
The following sections discuss the use of hydrotalcite as a filler and reinforcement in
composite materials, as an additive in coatings and paints, and in pharmaceutical and
personal care formulations. The next section discusses the applications of hydrotalcite
in water treatment, soil remediation, and battery and energy storage. The final section
summarizes the future prospects and challenges of hydrotalcite, including emerging
research areas, challenges and limitations, and potential for further industrial
applications.
This paper provides a comprehensive overview of the properties and applications of
hydrotalcite. It is intended to be a valuable resource for researchers, engineers, and
other professionals who are interested in this versatile material.
Catalytic Application of Hydrotalcite-Based Materials in Organic Transformation
Page: 187-209 (23)
Author:
DOI: 10.2174/9789815256116124010008
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Abstract
Hydrotalcite-based materials or Hydrotalcites (HTs) have gained significant
attention in recent years as efficient and versatile catalysts for various organic
transformation reactions. The tunable surface properties, high surface area, and
excellent thermal stability make them ideal catalysts for a range of chemical reactions.
This book chapter provides an overview of the recent advances in the application of
hydrotalcite-based materials as catalysts in organic transformations. The chapter
highlights the various catalytic reactions where hydrotalcite-based materials have
shown significant potential in the synthesis of a range of heterocycles such as
chromenes, pyrans, pyrazoles, and triazoles. as well as oxidation, reduction, and C-C
bond formation reactions. The chapter also discusses the various modifications that can
be made to hydrotalcite-based materials to enhance their catalytic activity, selectivity,
and stability by tailoring the electronic structure of the catalysts and supports.
Additionally, the chapter covers the use of hydrotalcite-based materials in the synthesis
of fine chemicals, pharmaceuticals, and polymers. Overall, this book chapter provides a
comprehensive overview of the catalytic application of hydrotalcite-based materials in
organic transformations. It will be of great interest to researchers and professionals in
the fields of catalysis, organic chemistry, and materials science, as well as to those
interested in developing more sustainable and efficient catalytic processes.
Synthesis of Heterocyclic Compounds Using Hydrotalcite
Page: 210-229 (20)
Author:
DOI: 10.2174/9789815256116124010009
PDF Price: $15
Abstract
Today, a promising technique for creating various biologically active
organic compounds is the one-pot synthesis employing materials based on hydrotalcite.
One-pot synthesis is an effective method for creating complex organic compounds
because it includes the simultaneous production of many bonds and functional groups
in a single reaction vessel. Layered double hydroxides (LDHs) called hydrotalcites
have a special structural makeup that makes them suitable for usage as catalyst
supports. The one-pot synthesis method using HT-based materials has a number of
benefits, including shorter reaction times, increased product yields, and simpler
reaction procedures. Utilising HT-based materials is also economical and friendly to
the environment. The chapter describes a variety of one-pot methods for the creation of
different heterocycles using hydrotalcites as effective catalysts.
Synthesis of Organic Molecules Using Hydrotalcite Based Materials
Page: 230-270 (41)
Author:
DOI: 10.2174/9789815256116124010010
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Abstract
Hydrotalcites (HTs) belong to layer double hydroxide (LDH) structure and
are the anionic clays that contain a double-layered structure similar to brucite [Mg
(OH)2
]. The layering structure allows the intercalation with a variety of anionic species,
oxometallates, and palmitoleates including absorbed water in the interlayer as well as
on the surface. Hydrotalcites (HTs) are the high-performance solid catalysts for the
one-pot synthesis of organic compounds in the industry as well as the laboratory by the
various chemical transformations such as Claisen-Schmid, aldol, Knoevenagel
condensations, and Michael addition, isomerization, and Friedel-Craft alkylation owing
to their surface Lewis base catalyst. This chapter offers an exposition on the diverse
strategies employed for crafting various organic scaffolds by using Hydrotalcites as a
catalyst and their applications within the spheres of biomedical and pharmaceutical
industries.
Recent Trends in the Application of Hydrotalcite based Materials in Organic Synthesis
Page: 271-328 (58)
Author:
DOI: 10.2174/9789815256116124010011
PDF Price: $15
Abstract
Hydrotalcites (HT) and hydrotalcite-based materials are viewed as attractive
and feasible choices among heterogeneous catalysts, particularly in organic catalytic
transformations. These catalysts have been widely researched as promising candidates
in one-pot organic synthesis. They are synthesised via the standard co-precipitation
method and can be used as support for transition metals and nanomaterials. Compared
to the corrosive, hard to reutilise and, detrimental to the environment homogenous
catalysts, HTs are high-functioning alternatives that deliver several benefits like
profitable yields, recyclability and excellent selectivity. They are being studied today as
precursors for a variety of scientific purposes such as in the production of renewable
fuels, polymers, olefins and pharmaceuticals. Such processes involve essential organic
reactions like isomerisation, oxidation, hydrogenation, methanation, nucleophilic
additions, transesterification, and many more. In this chapter, examples of such organic
reactions where hydrotalcite-based materials posed as an optimal catalyst are discussed.
One-Pot Synthesis Of Organic Molecules Using Hydrotalcite-Based Materials
Page: 329-362 (34)
Author:
DOI: 10.2174/9789815256116124010012
PDF Price: $15
Abstract
The one-pot reaction has recently received a lot of attention due to its
significant advantages over traditional multi-step reactions. One of the main advantages
of one-pot reactions is that it can save time and resources by eliminating the need for
multiple reaction steps and purification processes. It can lead to the more efficient and
cost-effective synthesis of target molecules. In addition, one-pot reactions can also
frequently be conducted under milder reaction conditions, such as lower temperatures
and pressures, resulting in higher yields and fewer side reactions. They can also reduce
the formation of hazardous waste and environmental impact. One-pot reactions also
offer more opportunities for synthetic creativity, as they allow for the simultaneous
manipulation of multiple functional groups in a single reaction vessel. As a result, new
synthetic pathways and novel compounds might be discovered.
In recent years, the combination of one-pot reactions and hydrotalcite has gained
significant importance recently due to their complementary advantages. Hydrotalcite is
a mineral with the chemical formula Mg6Al2
(OH)16CO3
.4H2O and is commonly found
in primary and ultrabasic igneous rocks, serpentinites, and carbonate-rich sediments. It
is made up of interlayer anions like carbonate or nitrate and positively charged layers
of magnesium and aluminum hydroxides. The layers of magnesium and aluminum
hydroxides, which are positively charged, have a large surface area and a net negative
charge in hydrotalcite as a result of the interlayer anions. Its large surface area and net
negative charge allow it to stabilize reactant molecules, enhancing the yield as well as
the selectivity of the expected product. Additionally, altering the interlayer anions, the
Mg/Al ratio, and doping with additional metal ions can further improve the catalytic
activity of hydrotalcite.
Compared to traditional catalysts, such as metal salts or complexes, hydrotalcite offers
several advantages, including high stability, low toxicity, and easy separation from the
reaction mixture. As a result, combining one-pot reactions with hydrotalcite as a
catalyst can lead to more efficient and sustainable synthetic processes with greater
synthetic creativity. Therefore, the aim of the book chapter is to summarize recent
examples of one-pot reactions in which hydrotalcites have been used as catalysts. By exploring these examples, readers can gain insights into the potential applications of
hydrotalcite as a flexible and efficient catalyst for organic reactions.
Introduction
Hydrotalcite-based materials, characterized by their unique composition are integral to diverse applications in heterogeneous catalysis and beyond. Renowned for their catalytic prowess, these compounds serve as versatile bases for organic reactions, support structures for metal catalysts, and facilitators in organic transformations and water treatment. This comprehensive book introduces readers to hydrotalcite-like compounds, with ten chapters exploring variations in metal ion ratios and interlayer anions, and their impact on properties crucial for industrial applications (ranging from industrial catalysis to medicine). Key Features • Detailed exploration of hydrotalcite and hydrotalcite-like compounds • Recent trends and applications in industrial catalysis, organic synthesis, and environmental remediation • Hydrotalcite synthesis including methods like coprecipitation, sol-gel processing, and advanced techniques • Contributions from leading researchers in the field with references • Comprehensive overview for each topic suitable for both academics and industry professionals With its exhaustive coverage of hydrotalcite-based materials and their multifaceted applications, this book promises to be an indispensable resource for anyone who wants to understand the utilization of hydrotalcites for advanced catalytic processes.