Up until a few decades ago, chalcogen chemistry was mainly represented by the chemistry of sulfur-containing compounds. However, with the rise in research around selenium and tellurium compound chemistry, the field has developed significantly as it continues to uncover and understand the peculiarities chalcogens exhibit. Taking an introductory approach, this book is the foundation to the subject that has been long needed. Covering organic and inorganic synthesis, structural properties, coordination chemistry and computational modelling, all key classes of chalcogen compounds are illustrated. Applications across materials science, biology, pharmaceutical science and environmental topics highlight to readers the impact of chalcogen chemistry in many aspects of research. Edited by international leaders in the field, Chalcogen Chemistry brings together contributions from acclaimed researchers around the world. This book is ideal for newcomers and established researchers, and provides the first building block to uncovering this fascinating field.

Polyoxometalates are anionic metal-oxo nanoclusters, which constitute a unique class of compounds owing to their rich solution equilibria and their unique compositional, electronic, reactive, and structural diversity. This book reviews metal-oxide cluster chemistry by covering topics ranging from fundamental aspects (i.e., structure, properties, self-assembly processes, derivatization) to functional materials that incorporate these molecular units, as well as their applications in the fields of current socioeconomic interest, such as energy storage systems, catalysis, molecular electronics, and biomedicine. Edited by prominent researchers in the field of polymer and polyoxometalate chemistries, the book compiles contributions from some of the most distinguished and promising scientists worldwide in such a way that it will appeal to a general readership involved in research areas related to chemistry and materials science.

Borate-based phosphors have attracted much attention, due to their high optical stability, low-cost synthesis via conventional and non-conventional methods and resulting technology to be environmentally friendly. This book discusses the structural and chemical parameters of borates as a phosphor including suitable synthesis methods and proper characterization of materials. Further, it includes applications of borate materials such as photoluminescence, UV application, UVU application, photo therapy application and radiological applications. Features: Provides information on borate phosphors and their structure. Aids selection of proper structural and functional borates used in applications based on phosphor technology. Discloses the modification in properties of borate functional group upon mixing or substitution with other metallic functional groups. Discusses biological applications such as photo-thermal heating-based therapy, temperature sensors, imaging, and diagnosis. Includes current trends and innovations, limitations and challenges, prospects, and scope in each chapter. This book is aimed at researchers and graduate students in inorganic materials, luminescent/optical materials, materials science/engineering, and physics.

Chemistry: The Key to our Sustainable Future is a collection of selected contributed papers by participants of the International Conference on Pure and Applied Chemistry (ICPAC 2012) on the theme of "Chemistry: The Key for our Future" held in Mauritius in July 2012. In light of the significant contribution of chemistry to benefit of mankind, this book is a collection of recent results generated from research in chemistry and interdisciplinary areas. It covers topics ranging from nanotechnology, natural product chemistry to analytical and environmental chemistry. Chemistry: The Key to our Sustainable Future is written for graduates, postgraduates, researchers in industry and academia who have an interest in the fields ranging from fundamental to applied chemistry.

New Fluorinated Carbons: Fundamentals and Applications is the second volume in Alain Tressaud's Progress in Fluorine Science series. This volume provides an overview of cutting-edge research and emerging applications using new fluorinated carbon materials such as fullerenes, carbon nanotubes, polycyclic aromatic molecules, carbon nanofibers, and graphenes. Edited by recognized experts Olga Boltalina and Tsuyoshi Nakajima, this book includes valuable chapters on syntheses, structure analyses, and chemical and physical properties of fluorinated carbons written by leaders in each respective field. The work also explores the diverse practical applications of these functional materials-from energy storage and energy conversion devices to molecular electronics and lubricants.

The Chemistry and Biology of Nitroxyl (HNO) provides first-of-its-kind coverage of the intriguing biologically active molecule called nitroxyl, or azanone per IUPAC nomenclature, which has been traditionally elusive due to its intrinsically high reactivity. This useful resource provides the scientific basis to understand the chemistry, biology, and technical aspects needed to deal with HNO. Building on two decades of nitric oxide and nitroxyl research, the editors and authors have created an indispensable guide for investigators across a wide variety of areas of chemistry (inorganic, organic, organometallic, biochemistry, physical, and analytical); biology (molecular, cellular, physiological, and enzymology); pharmacy; and medicine. This book begins by exploring the unique molecule's structure and reactivity, including important reactions with small molecules, thiols, porphyrins, and key proteins, before discussing chemical and biological sources of nitroxyl. Advanced chapters discuss methods for both trapping and detecting nitroxyl by spectroscopy, electrochemistry, and fluorescent inorganic cellular probing. Expanding on the compound's foundational chemistry, this book then explores its molecular physiology to offer insight into its biological implications, pharmacological effects, and practical issues.

Anyone who has taught materials chemistry will be aware that it is an expansive subject. Whilst this makes it exciting, it can also overwhelm students who end up lost in the detail. This book provides an antidote. Aimed at advanced undergraduate and graduate students, Core Concepts for a Course on Materials Chemistry is a distillation of the fundamental topics born out of the author's 30 years of teaching experience. Covering many broad themes in materials chemistry, this textbook provides teachers and students with the essential concepts in a concise form. Taking a systematic approach, the book is arranged into seven chapters: Solid State Structure Defects and Non-stoichiometry Thermal Properties Electrical Properties Magnetic Properties Optical Properties Materials Synthesis and Fabrication The author adopts a telescopic approach to each area, capturing the broader picture before detail is revealed, allowing students to readily make logical connections. The strong visual focus conveys complex ideas in a comprehensive style, supporting the physical and analytical presentation. A note on how to effectively use the book is included for instructors, making this text easy to embed in existing or new materials chemistry courses. Students will benefit from the numerous examples that place the topics in the right context, and the exercises that test comprehension. Suitable for chemists and materials scientists, this book is ideal for self-study, as well as for the efficient teaching of a course.

A stand-alone, monograph present results on mechanochemical synthesis of nanostructured composite materials on the base of inorganic and organic components The book summarizes and systematizes the results of a fundamentally new complex approach to the creation of composite polymer-inorganic systems by mechanochemical treatment, both as a result of the traditional approach with the use of dynamic mills (mechanical reactors) and ultrasonic action on powder mixtures In addition, the book will present a chapter that will focus on the method of mechanochemical preparation of materials for high-energy systems, which are the most promising, since it allows the most productive management of the formation of new structural compositions that increase the energy intensity of the system.

Organic chemistry research has moved rapidly toward synthesis and medicinal application of nitrogen-containing compounds such as triazenes, triazines, and hydroxytriazenes due to their excellent biological activities. Many of them are presently in clinical trials. Triazene compounds have excellent medicinal properties and limited toxicity. Hydroxytriazenes are excellent chelating agents for transition metals. Newer studies show very promising biological and medicinal applications of these classes of compounds. Hydroxytriazenes and Triazenes: The Versatile Framework, Synthesis, and Medicinal Applications highlights synthetic methods, recent advances, and potential applications of triazines, triazenes, and hydroxytriazenes. This book includes holistic information on synthetic methods for novel compounds based on this moiety, up-to-date information on the how and why of their diverse or even multitargeted medicinal application, and future state of the art of both aspects. Other features include: Highlights recent advances and diverse possible applications of biological functions Covers the chemistry of triazine, triazene, and hydroxytriazene systems On the basis of in silico predictions, the book highlights synthetic methods and their applications A valuable source of information for those actively engaged in medicinal chemistry, drug discovery, and synthetic organic chemistry

Presents cutting-edge research in biomedical engineering from materials, devices, imaging, and information perspectives All chapters are results of collaborative research in engineering and life sciences Useful resource for researchers, students, and general readers in biomedical engineering

The principal idea of this volume is to offer a Capita Selecta of unconventional and thought-provoking topics in organometallic chemistry, presented by experts in each field. As intended, this approach leads either to reviews covering a specific uncommon class of organometallic compounds or to overviews which relate uncommon physical properties with various classes of organometallic compounds. The contributions are streamlined thus onto two main axes - unusual properties reflecting structures and bonding situations, on the one hand, and uncommon structural features or structure-reactivity relationships, on the other. Extensive cross-referencing of useful information is provided, making this volume accessible for people working in rather different areas of organometallic chemistry.

The synthesis of molecules with 'extreme' properties is a challenge for all those working in organometallic chemistry, irrelevant of theoretical/computational, synthetic or application interests. This book presents case studies at the interface of these overlapping interests.

Unusual Structures and Physical Properties in Organometallic Chemistry:

• Provides test cases for computational and theoretical models
• Presents a challenge for synthetic chemists
• Provides ideal show cases for analytical techniques

Handbook on the Physics and Chemistry of Rare Earths is a continuing series of books covering all aspects of rare earth science, including chemistry, life sciences, materials science, and physics. The handbook emphasizes rare earth elements [Sc, Y and the lanthanides (La through Lu)] but, when relevant, information also is included about the closely related actinide elements. The individual chapters are comprehensive, broad, up-to-date critical reviews written by highly experienced invited experts. The series, which was started in 1978 by Professor Karl A. Gschneidner, Jr., combines and integrates both the fundamentals and applications of these elements and now publishes two volumes a year.

An in-depth discussion of the thermodynamics and kinetics of natural waters

Divided into three major parts–structure of matter, chemical thermodynamics, and chemical kinetics– physical chemistry is concerned with the measurement, description, and prediction of the characteristics of chemical systems and their interaction with each other with respect to the transfer of mass and energy. Physical Chemistry of Natural Waters explores how the basic concepts of physical chemistry can be used to understand the chemistry of natural waters, with most of the text confined to chemical thermodynamics and kinetics.

The extensive material in this book is the result of a course in marine physical chemistry that the author has taught over the past decade. Dr. Millero incorporates his own personal interest in solution physical chemistry and his approach to understanding the physical chemistry of seawater with the text’s vast coverage of the physical chemistry of liquid phases. In addition, detailed reviews of the basics of thermodynamics and kinetics provide a comprehensive overview for a clearer understanding of the topics covered.

Environmental and physical chemists conducting research on water, seawater, rivers, lakes, and groundwater as well as graduate students studying environmental chemistry will find Physical Chemistry of Natural Waters a solid foundation on the subject of the physical chemistry of natural waters.

This book describes the luminescence mechanism of polynuclear lanthanide complexes, focusing on energy transfer processes using a combination of experimental and theoretical approaches. Lanthanide complexes show intense luminescence from the lanthanide ion through sensitization by the organic ligands. The high chromaticity of the emission and the long lifetimes of the complexes are particularly attractive for applications such as organic light-emitting diodes and bioprobes. Polynuclear lanthanide complexes (coordination polymers and clusters) have attracted considerable interest for functionalization by energy transfer between lanthanide ions. At the same time, such extra processes complicate the luminescence mechanism, hindering the rational design of functional polynuclear lanthanide complexes. Firstly, the book explains the principle of the theoretical methods, and then describes the concentration-quenching mechanism in coordination polymers. It also examines the effect of intrinsic spin-orbit coupling arising from lanthanide ions on the ligand-to-lanthanide energy transfer efficiency and the mechanism of back energy transfer (the opposite of sensitizing energy transfer) in lanthanide clusters. This sets the stage for the final topic: the suppression of back energy transfer by energy transfer between lanthanide ions in lanthanide clusters, which is of critical importance, showing that the lanthanide clusters can be considered a new generation of functional and efficient luminescent material and could also provide a breakthrough in lanthanide photophysics.

This book covers the role of water in global atmospheric phenomena, focussing on the physical processes involving water molecules and water microparticles. It presents the reader with a detailed look at some of the most important types of global atmospheric phenomena involving water, such as water circulation, atmospheric electricity and the greenhouse effect. Beginning with the cycle of water evaporation and condensation, and the important roles played by the nucleation and growth processes of water microdroplets, the book discusses atmospheric electricity as a secondary phenomenon of water circulation in the atmosphere, comprising a chain of processes involving water molecules and water microdroplets. Finally, the book discusses aspects of the molecular spectroscopy of greenhouse atmospheric components, showing how water molecules and water microdroplets give the main contribution to atmospheric emission in the infrared spectrum range. Featuring numerous didactic schematics and appendices detailing all necessary unit conversion factors, this book is useful to both active researchers and doctoral students working in the fields of atmospheric physics, climate science and molecular spectroscopy.

This book discusses the extraction, purification, modification, and processing of biobased materials and their various industrial applications, across biomedical, pharmaceutical, construction, and other industries. It includes contributions from experts on hybrid biopolymers and bio-composites, bioactive and biodegradable materials, bio-inert polymers, natural polymers and composites, and metallic natural materials. Therefore, this encyclopedia is a useful reference for scientists, academicians, research scholars, and technologists. Major challenges of biobased materials are their efficient development, cost-effective, and green & environment friendly production/applications. This encyclopedia answers these challenges to professionals and scientists for proper utilization of biobased materials. It presents the recent practices of biobased materials technology in different scientific and engineering domains. It helps the bounded industrial outcomes to reach the general readership of different domains. This encyclopedia bridges the technological gaps between the industrial and academic professionals and the novice young students/scholars. The interdisciplinarity of this encyclopedia makes it unique for a wide readership. The topic of biobased materials is currently popular in the scientific community, working in such following areas as Recycled materials, Renewable materials, Materials for efficiency, Materials for waste treatment, Materials for reduction of environmental load, Materials for easy disposal or recycle, Hazardous free materials, Materials for reducing human health impact, Materials for energy efficiency, Materials for green energy, etc. This is a relatively hot topic in materials science and has strong demands for energy, material and money savings, as well as heavy contamination problems, despite that the area of biobased materials belongs to most important fields of modern science & technology, no important encyclopedias have been published in the area of "biobased materials"

This unique book presents an integrated approach to the chemistry of art materials, exploring the many chemical processes involved. The Chemistry and Mechanism of Art Materials: Unsuspected Properties and Outcomes engages readers with historical vignettes detailing examples of unexpected outcomes due to materials used by known artists. The book discusses artists' materials focusing on relevant chemical mechanisms which underlie the synthesis and deterioration of inorganic pigments in paintings, the ageing of the binder in oil paintings, and sulfation of wall paintings as well as the toxicology of these pigments and solvents used by artists. Mechanisms illustrate the stepwise structural transformation of a variety of art materials. Based on the author's years of experience teaching college chemistry, the approach is descriptive and non-mathematical throughout. An introductory section includes a review of basic concepts and provides concise descriptions of analytical methods used in contemporary art conservation. Additional features include: Illustrations of chemical reactivity associated with art materials Includes a review of chemical bonding principles, redox and mechanism writing Covers analytical techniques used by art conservation scientists Accessible for readers with a limited science background Provides numerous references for readers seeking additional information

Volume 2 presents the latest applications of M ssbauer spectroscopy to the study of magnetic materials. Topics include: Surface and thin film analysis, iron-based amorphous ribbons and wires, diffusion studies, analytical methods for M ssbauer spectral analysis of complex materials, and quasicrystalline materials among others. These discussions will be invaluable to materials scientists, inorganic chemists, and solid-state chemists.

Inspired by a symposium held at the University of Southern California, in March 1988, dedicated to Paul van R. Schleyer, contributors examine the role of 'hypercarbons' in several areas of chemistry in this book. The multicenter bonding of 'hypercarbons' relative to the chemistry of main group elements, organometallics, cluster chemistry, carbocations, and hydrocarbon chemistry are systematically covered.

This book presents the main research advances in the field of photofunctional rare earth hybrid materials. The first chapter discusses the fundamental principles, ranging from rare earth, rare earth luminescence, luminescent rare earth compounds and photofunctional rare earth hybrid materials. The main body of the book consists of six chapters exploring different kinds of photofunctional hybrid materials, such as hybrids based on organically modified silica; organically modified mesoporous silica; functionalized microporous zeolite and metal-organic frameworks; polymer or polymer/silica composite; and multi-component assembly of hybrids. It also includes a chapter introducing the photofunctional application of these hybrid materials. It is a valuable resource for a wide readership in various fields of rare earth chemistry, chemical science and materials science.

This book presents an uncritical summary of thermodynamic data for common minerals and compounds at ambient surface conditions, with complete references for the data. Values of the enthalpy of formation, Gibbs energy of formation, and entropy for common elements, aqueous species, gases, liquids, minerals (many of which are usually not found in critical tables) and related substances are brought together. Because the summary is uncritical, all available values for the various species are included, allowing readers to make a choice among the data compiled by various groups. The table is an important reference for geochemists, geologists, and chemists.

Organophosphorus Chemistry presents a groundbreaking resource in this branch of organic chemistry that demonstrates how phosphorus-containing compounds can be manipulated in a variety of organic reactions. The authors give an overview of the newest trends and synthesis strategies, introduce bioactive and environmentally friendly organophosphorus compounds and show their importance in mainstream organic chemistry.

The Biological Chemistry of Magnesium Edited by J. A. Cowan Recent years have witnessed a revolution in the understanding of magnesium biochemistry, especially the pivotal role of magnesium ion in nucleic acid biochemistry. This graduate text presents a unique and comprehensive review of all major areas of current research interest, from inorganic chemistry, nucleic acid biochemistry, and enzymology through ribozyme activation, drug-magnesium-DNA interactions, and magnesium transport by selective membrane channels. Introductory chapters provide a useful review for the non-specialist, including descriptions of essential solution chemistry and physical methods for monitoring magnesium biochemistry. Its readable style and emphasis on understanding at the molecular level makes The Biological Chemistry of Magnesium accessible and relevant to researchers and graduate students in the field, as well as non-specialists in biochemistry, molecular biology, biotechnology, bioinorganic chemistry, and pharmaceutical sciences. Also available from VCH: Inorganic Biochemistry: An Introduction J.A. Cowan Hardcover (ISBN 1-56081-537-X) Manganese Redox Enzymes V.L. Pecoraro, ed. Hardcover (ISBN 0-89573-729-9) The Bioinorganic Chemistry of Nickel J.R. Lancaster, Jr. Hardcover (ISBN 0-89573-338-2)