Most fields of science, applied science, engineering, and technology deal with solutions in water. This volume is a comprehensive treatment of the aqueous solution chemistry of all the elements. The information on each element is centered around an E-pH diagram which is a novel aid to understanding. The contents are especially pertinent to agriculture, analytical chemistry, biochemistry, biology, biomedical science and engineering, chemical engineering, geochemistry, inorganic chemistry, environmental science and engineering, food science, materials science, mining engineering, metallurgy, nuclear science and engineering, nutrition, plant science, safety, and toxicology.

The first f-block elements were discovered in the 18th and 19th centuries, since the advent of the cyclotron many more of them have been isolated. The applications of these elements range from smoke detectors to catalytic converters and they are used widely in industry, for example, in the refining of oil and the manufacture of glass and ceramics.;This systematic introduction to the chemistry of the lanthanide and actinide elements illustrates the main features of f-block chemistry and the important applications of the elements and their compounds. Details and references from research are included. Aimed at advanced undergraduate students learning about this area of inorganic chemistry, this book provides a detailed introduction to the topic. The book should also act as a useful reader for first year postgraduate students and researchers, particularly those from a non-inorganic chemistry background, requiring an overview of the area.

Water Oxidation Catalysts, Volume 74, the latest release in the Advances in Inorganic Chemistry series, presents timely and informative summaries on current progress in a variety of subject areas. This acclaimed serial features reviews written by experts in the field, serving as an indispensable reference to advanced researchers. Users will find this to be a comprehensive overview of recent findings and trends from the last decade that covers various kinds of inorganic topics, ranging from theoretical oriented supramolecular chemistry, to the quest for accurate calculations of spin states in transition metals.

Green chemistry promotes improved syntheses as an intellectual endeavour that can have a great impact both on preserving and utilizing our planet's finite resources and the quality of human life. This masterful accomplishment provides an evaluation of environmental impact metrics according to life cycle assessment analysis based on the Mackay compartment environmental model and Guinee environmental impact potentials formalism. Assumptions, limitations, and dealing with missing data are addressed. Best literature resources for finding key toxicological parameters are provided and applied to individual reactions as well as entire synthesis plans, in order to target molecules of interest. Key Features: Provides an evaluation of environmental impact metrics according to life cycle assessment analysis Summarises safety-hazard metrics according to the same model as life cycle assessment including occupational exposure limits, risk phrases, flammability, and other physical parameters The book will be useful in a range of chemistry courses, from undergraduate to advanced graduate courses, whether based in lectures, tutorials or laboratory experiments

This is the first comprehensive book on fine particle synthesis that ranges from fundamental principles to the most advanced concepts, highlighting monodispersed particles from nanometers to micrometers. Describes mechanisms of formation and specific characteristics of each family of compounds while identifying problems and proposing solutions Offering a systematically organized review of the subject and including recent remarkable developments, Fine Particles contains subsections that analyze growth processes, characterize products, and delineate physical and chemical results based on causality arranges organic and inorganic materials according to their chemical composition covers forced hydrolysis and hydrolysis of metal and silicon alkoxides in homogeneous solutions details controlled double jet and Ostwald ripening processes examines emulsion and dispersion polymerization discusses surface modification of polymer and inorganic particles considers the formation of magnetic particles, fine composites, and nanocrystalline luminous materials and more Replete with 1700 references and over 600 photographs, drawings, tables, and equations, Fine Particles is useful for physical, surface, colloid, inorganic, organic, polymer, medicinal, and analytical chemists; chemical engineers; ceramicists; materials scientists; metallurgists; pharmacists; biochemists; biophysicists; biotechnologists; biomaterials specialists; and graduate students in these disciplines.

Humans first used carbon as chars from firewood in ritual paintings and primitive metallurgical processes. Natural forms of carbon have been known since antiquity, yet the knowledge of the carbon element in chemistry and its technical applications on a larger scale are a relatively recent development. The industrial revolution in Europe two centuries ago led the way to the numerous applications of these graphitic forms that are still used today. Graphite and Precursors features short tutorial articles on different topics related to the science and technology of carbons intended for engineers, students of Materials Science and scientists who are seeking a fundamental understanding without "reinventing the wheel." This first volume of the World of Carbon book series focuses on graphite and its precursors, including its origin and various implications. The basic properties of hexagonal graphite are developed, and several theoretical and experimental approaches explain why this crystalline solid is fascinating in solid state physics. Also featured are the numerous applications connected to thermal, mechanical and chemical graphites, as well as their various industrial uses in polycrystalline form. Finally, carbon precursors are introduced.

Transition metal carbonyl clusters (TMCCs) continue to inspire great interest in chemical research, as much for their fascinating structures as for potential industrial applications conferred by their unique properties. This highly accessible book introduces the bonding, structure, spectroscopic properties, and characterization of clusters, and then explores their synthesis, reactivity, reaction mechanisms and use in organic synthesis and catalysis.

Transition Metal Carbonyl Cluster Chemistry describes models and rules that correlate cluster structure with electron count, which are then applied in worked examples. Subsequent chapters explain how bonding relates to molecular structure, demonstrate the use of spectroscopic techniques such as NMR, IR and MS in

cluster chemistry, and outline the factors contributing to the stability, dynamics and reactivity of clusters. The second part of this book discusses the synthesis and applications of TMCCs.? It emphasizes the differences between the reactivities of clusters vs. mononuclear metal complexes, contingent to the availability of multiple-bonding sites and heterosite reactivity.? The final chapters discuss reactions in which clusters act as homogeneous catalysts; including discussion on the use of solid and biphasic liquid-liquid supported clusters in heterogeneous catalysts.

A useful reference for those commencing further research or post-graduate study on metal carbonyl clusters and advanced organometallic chemistry, this book is also a cornerstone addition to academic and libraries as well as private collections.

"Provides an overview of scientific and technological issues in environmental applications of carbon materials. Emphasizes the versatility of carbon materials in both gas- and liquid-phase environmental applications, including a discussion of emerging technologies. Highlights the power and potential opportunities afforded by NMR spectroscopy for understanding the interaction of carbon materials with adsorbed molecules."

Boasting numerous industrial applications, inorganic chemistry forms the basis for research into new materials and bioinorganic compounds such as calcium that act as biological catalysts. Now complete, this highly acclaimed series presents current knowledge in all areas of inorganic chemistry, including chemistry of the elements; organometallic, polymeric and solid-state materials; and compounds relevant to bioinorganic chemistry.

Inorganic Biochemistry An Introduction Second Edition J.A. Cowan Developments in the expanding field of inorganic biochemistry have led to major additions to this important teaching text. Like the earlier edition, the second edition does not aim to be comprehensive, but to illustrate the use of basic principles to tackle important problems in inorganic biochemistry. New features of the second edition include a section on basic kinetic and thermodynamic principles in the first chapter; coverage of iron response proteins, ribozymes, and radiopharmaceuticals; a new case study of bleomycin; a comprehensive set of problems and study questions; complete literature citations; and review questions after most of the summary sections. Inorganic Biochemistry: An Introduction, Second Edition will be of great value to senior-level undergraduates and beginning graduate students in inorganic chemistry and biochemistry. It also will be a valuable reference for biological, inorganic and organic chemists; chemical and environmental engineers; researchers in molecular biology and medical sciences; and biophysicists.

Even at the beginning of the new millenium the rare earths still remain, to a certain extent, a mystery. The chapters in this volume will help to unravel some of these. In the filling of the 4f electronic orbitals the lanthanides defy the elementary aufbau principle that underlies the periodic sequence of the elements, and the authors of the first chapter introduce the readers to the basic physics of the orbital collapse leading to that failure. Furthermore an explanation is offered in terms of double-well potentials. The phenomenon is illustrated using the valence transitions observed in some of the rare earth atoms, including Sm group metals and the higher oxides of cerium, praseodymium and terbium. In the second chapter the synthesis and structure of the many types of rare earth halides are described. They have been described as simple, complex, binary, ternary and multinuclear complex, and other categories needed to deal with the most studied of the rare earth compounds. The structure types are skillfully illustrated to show the elementary architecture of each type.
In chapter three the authors discuss the science and applications of rare earth super ionic conductors as solid electrolytes. Conduction by oxygen and fluorine anions as well as hydrogen and other cations associated with these electrolytes is emphasized. They deal with extrinsic and intrinsic types together with their associated structures and structural types including structural defects. The chapter concludes with an outline of the many applications of solid electrolytes.
Chapter four introduces the reader to the principles that underlie thermoluminescence and its application to dosimetry and provides detailed information on the R-activated phosphors that support dosimetry. This is a selective review of detailed literature based on the areas making most progress.
The final chapter elaborates on the data gained by the studies and interpretation around the analytical separation of the individual rare earth elements utilizing chromatographic techniques. The authors describe the fundamental chemistry that underpins contemporary analytical separation techniques for lanthanide separation and analysis. This is done after a description of the rich assortment of separation methods in use has been introduced.

This book summarizes recent progresses in inorganic fluorine chemistry. Highlights include new aspects of inorganic fluorine chemistry, such as new synthetic methods, structures of new fluorides and oxide fluorides, their physical and chemical properties, fluoride catalysts, surface modifications of inorganic materials by fluorination process, new energy conversion materials and industrial applications.

Fluorine has quite unique properties (highest electronegativity; very small polarizability). In fact, fluorine is so reactive that it forms fluorides with all elements except with the lightest noble gases helium, neon and argon. Originally, due to its high reactivity, fluoride chemistry faced many technical difficulties and remained undeveloped for many years. Now, however, a large number of fluorine-containing materials are currently produced for practical uses on an industrial scale and their applications are rapidly extending to many fields.

Syntheses and structure analyses of thermodynamically unstable high-oxidation-state fluorides have greatly contributed to inorganic chemistry in this decade. Fluoride catalysts and surface modifications using fluorine are developing a new field of fluorine chemistry and will enable new syntheses of various compounds. The research on inorganic fluorides is now contributing to many chemical energy conversion processes such as lithium batteries. Furthermore, new theoretical approaches to determining the electronic structures of fluorine compounds are also progressing. On the industrial front, the use of inorganic fluorine compounds is constantly increasing, for example, in semi-conductor industry.

"Advanced Inorganic Fluorides: Synthesis, Characterization and Applications" focuses on these new features in inorganic fluorine chemistry and its industrial applications. The authors are outstanding experts in their fields, and the contents of the book should prove to be of valuable assistance to all chemists, graduates, students and researchers in the field of fluorine chemistry.

Series Information:
Modern Concrete Technology

Praise for the First Edition:

"Very useful for researchers in solid-state chemistry and as a textbook of advanced inorganic chemistry for PhD students." —Advanced Materials.

This book provides unified coverage of the structure, properties, and synthesis of transition metal oxides. Written by two world-class scientists, it offers both an excellent window on modern solid-state chemistry and a gateway to understanding the behavior of inorganic solids.

Scientists and advanced students in inorganic and solid-state chemistry, materials science, ceramics, and condensed matter science will welcome this updated Second Edition, which features new or expanded material on:

• Oxyanion derivatives of cuprates, mercury cuprates, ladder compounds, and new oxide systems
• Giant magnetoresistance, superconductivity, and nonlinear materials
• Recently developed synthetic strategies and examples, including soft chemistry routes

Plus:

• Hundreds of illustrations
• Helpful references.

This practical guide to the trace analysis of metals and alloys details minor, trace, and ultratrace methods; addresses the essential stages that precede measurement; and highlights the measurement systems most likely to be used by the pragmatic analyst. Features key material on inclusion and phase isolation, never-before published in any English-language reference Designed to provide useful maps and signposts for metals analysts who must verify that stringent trace level compositional specifications have been met, Trace Elemental Analysis of Metals examines sampling, contamination control, isolation, and preconcentration covers molecular absorption, atomic absorption, atomic emission, mass spectrometry, and other measurement systems discusses the critical importance of inclusions and phases in obtaining accurate trace determinations explores quality issues surrounding method validation, analytical control verification, and reference material needs defines a style for treating results slightly above the noise limit of the instrumentation provides painstakingly referenced, step-by-step instructions for specific alloy systems and methodologies supplies a concise overview of the chemical and instrumental techniques widely available in industrial laboratories includes an easy-to-use glossary defining terms, specialized usage, and jargon related to trace work in metals and alloys reviews the conventions of reporting at, and near, the detection and quantification limits of a procedure and more Offering direction to analysts seeking consistent data while working within the limits of available technology, Trace Elemental Analysis of Metals is a valuable guide suited to analytical, inorganic, and materials chemists; spectroscopists; environmental scientists; and upper-level undergraduate and graduate students in these disciplines.

Magnetochemistry is a highly interdisciplinary field that attracts the interest of chemists, physicists and material scientists. Although the general strategy of theoretical molecular magnetism has been in place for decades, its performance for extended systems of interacting magnetic units can be very complicated. Professor Boca's book treats the "mosaic" of the theoretical approaches currently used in the field.

This book presents a review of the theoretical concepts of molecular magnetism. The first chapter of the book recapitulates the necessary mathematical background. An overview of macroscopic magnetic properties is then presented. Formulation of magnetic parameters and methods of their calculation are given, followed by a brief summary of magnetic behaviour. The core of the book deals with the temperature dependence of magnetic susceptibility for mononuclear complexes, dimers, and exchange-coupled clusters.

This book will be particularly useful for those scientists and students working in the field of molecular magnetism who need to refer to a complete and systematic treatment of the mathematics of magneto-chemical theory.

Chemistry has a vital role to play in materials processing and in the development of new materials that can meet the changing needs of today's technology. This volume addresses both the basic underlying principles and the technological relevance of major topics in advanced materials chemistry, including:

• Electron transfer salt-based conductors, superconductors, and magnets
• Advanced polymeric materials-functional electroactive polymers
• Polymers in electronics
• Chemical vapor deposition
• An introduction to the nonlinear optical properties of organic materials
• Nanoparticles and nanostructural materials
• Nanoporous materials
• Molecular precursor routes to inorganic solids
• Layered transition metal oxides and chalcogenides
• Biomaterials

Bringing together a battery of important information in a single source, this stand-alone reference is an invaluable companion for aspiring and practicing organic, inorganic, solid-state, and surface chemists, as well as polymer and materials scientists.

Understanding the mechanisms of crystallization processes on the molecular level is an essential step in the control of the formation of crystals. These crystals may be a desirable solid product or an undesirable precipitate. Crystallization Processes

• covers the theory, research, applications and control of crystallization processes from a homogeneous liquid to a solid phase.
• considers the behaviour of ions and molecules in homogeneous supersaturated solutions and also in liquid metals and ionic melts.
• discusses recent work on ionic solvation desolvation phenomena, association of ions and molecules in solution and precipitation and dissolution of crystals.
• includes the mechanism of crystallization of calcium carbonate and other simple inorganic electrolytes, amino acids, lipids and proteins.

This book by Kaplan and Vekhter brings together the molecular world of the chemist with the condensed matter world of the physicist. Prior to the collapse of the Soviet Union, chemists in the West devoted lit to relationships between molecular electronic structure and tle attention solid-state vibronic phenomena. Treating quantum mechanical problems wherein the adiabatic Born-Oppenheimer approximation fails was done by "brute force. " With bigger and better computers available in the West, molecular orbital calculations were done on observed and conceived static structures with little concern for any cooperativity of vibrational behavior that might connect these states. While it had long been understood in the West that situations do occur in which different static structures are found for molecules that have identical or nearly identical electronic structures, little attention had been paid to understanding the vibrational states that could connect such structures. It was easier to calculate the electronic structure observed with several possible distortions than to focus on ways to couple electronic and vibrational behavior. In the former Soviet Union, computational power was not as acces sible as in the West. Much greater attention, therefore, was devoted to conserving computational time by considering fundamental ways to han dle the vibrational connectivity between degenerate or nearly degenerate electronic states.

This special issue of "Carbon," a collection of reviewed papers, was presented at Symposium A, Fullerenes and Carbon Based Materials at the combined 1997 International Conference on Applied Materials/European Materials Research Society Spring meeting (ICAM'97/E-MRS'97) held in Strasbourg (France) from 16-20 June 1997.

140 presentations were given at the conference in seven different sessions. The most extensively addressed research fields were carbon materials in general, diamond-like carbon, pristine, polymeric and endohedral fullerenes, nanotubes, and carbonitrides.

Of accepted manuscripts, the largest number of contributions is dedicated to carbon materials in general and to fullerenes. Highlights in the former are the discussions on hydrogen-free carbons and on hard carbon coatings. In the fullerenes group many new results on polymeric structures and on endohedrally-doped higher fullerenes are reported.

The field of carbon nanotubes is strongly represented with reports on new techniques for the production of the tubes and where the analyses by scanning probe microscopy and light scattering are the central problems. Carbonitrides as well as a few contributions from related molecular materials like cubanes or oligophenylenes are included.

The symposium proved to be a valuable venue where new scientific and technological problems in the field of new materials were reported.

Metal-based drugs are a commercially important sector of the pharmaceutical business, yet most bioinorganic textbooks lack the space to cover comprehensively the subject of metals in medicine. Uses of Inorganic Chemistry in Medicine approaches an understanding of the topic in a didactic and systematic manner. The field of inorganic chemistry in medicine may usefully be divided into two main categories - drugs which target metal ions in some form, whether free or protein-bound, and secondly, metal-based drugs where the central metal ion is usually the key feature of the mechanism of action. This latter category can further be subdivided into pharmacodynamic and chemotherapeutic applications, as well as those of imaging. The book summarises the chemical and biological studies on clinically used agents of lithium, gold and platinum, as well as highlighting the research on prospective new drugs, including those based on vanadium and manganese. The coverage allows a clear distinction between pharmacodynamic and therapeutic properties of metal-based drugs and focuses not only on those clinical agents in current use, but also on new drugs and uses. This book serves to fill an important niche, bridging bioinorganic and medicinal chemistry and will undoubtedly be of use to senior undergraduates and postgraduates, as well as being an invaluable asset for teachers and researchers in the discipline.

Discover the exciting, promising field of molecular level artificial photosynthesis
This special volume of Progress in Inorganic Chemistry presents the theory and practice of molecular artificial photosynthesis-a field holding tremendous promise now that molecular solar energy materials are fast becoming competitive with their solid-state counterparts.
The only book on the market to address this important area of inorganic research, Molecular Level Artificial Photosynthetic Materials shows us, in effect, how to imitate the complex natural processes of photosynthesis-featuring state-of-the-art strategies and techniques for creating artificial photosynthetic devices at the molecular level. It takes a multidisciplinary approach, drawing on materials science techniques used in the design of solar energy devices, examining the molecular nature of the chemistry involved, and applying existing knowledge in inorganic photochemistry and photophysics to the growing pool of molecular photonic materials.
Composed of seven superbly crafted contributions by leading experts in the field, this comprehensive work
* Describes molecular components integrated within nanophase materials, gels, zeolites, thin films, and layered solids
* Uses novel time resolved vibrational spectroscopies to elucidate fundamental electron and energy transfer mechanisms in complex supramolecular compounds
* Highlights practical applications such as the conversion of light into electricity, solar detoxification of pollutants, and the production of useful fuels-including the splitting of water into hydrogen and oxygen
* Points to areas of future research and usefulness for inorganic photochemists, as well as for students, chemists, material scientists, physicists, and engineers in a wide range of fields

"Details the most recent advances in Laboratory Information Management Systems. Offers contemporary approaches to system development, design, and installation; system customization; software and hardware compatibility; quality assurance and regulatory requirements; and resource utilization."

Discusses the laboratory and industrial synthesis of nonionic surfactants. Furnishes exhaustive coverage of the most recent advances in nonionic surfactant organic chemistry. Analyzes a novel class of catalysts for the production of surfactants with highly narrow distributions.

Emphasizing the utility of copper-related compounds, this text illustrates the numerous current and potential uses from agricultural bactericides and wood preservatives to colourants and solar cells. It discusses the properties and behaviour of the copper ion, copper compounds' employment in organic polymerization and isomerization reactions, the enhancement of feed efficiencies and additives in plant and animal nutrition, and more.