Tandem Techniques Raymond P. W. Scott Chemistry Department, Georgetown University, Washington DC, USA and Chemistry Department, Birkbeck College, University of London, UK Analytical techniques based on separation processes, such as chromatography and electrophoresis, are finding a growing range of applications in chemical, pharmaceutical and clinical laboratories. The Wiley Separation Science Series provides the analyst in these laboratories with well focused books covering individual techniques, so that they can be applied more efficiently and effectively to contemporary analytical problems. Tandem Techniques describes the function and uses of instruments that comprise the combination of a separation technique (e.g. chromatography) with an identifying technique, (e.g. spectroscopy) for the rapid separation and identification of the components of complex mixtures. The basic principles of the commonly used separation techniques (i.e. gas chromatography, liquid chromatography, thin layer chromatography and capillary electrophoresis) are discussed, together with the basic principles of the spectroscopic techniques employed with them. The book is divided into four sections; the first dealing with the fundamental principles of separation and identification techniques; the second with gas chromatography tandem systems; the third with tandem systems associated with liquid chromatography and similar separation techniques; the fourth section with tandem instruments combined with capillary electrophoresis. The various interfaces involved are discussed and described in detail and, where possible, comparative performance data is presented particularly with respect to system sensitivity. The morerecent developments in the different techniques are included incorporating references published up to mid 1996. Tandem Techniques will be an essential handbook for all chemists involved in general analysis product assay and environmental monitoring. It will be particularly useful to those scientists concerned with the many and varied aspects of separation science.

The technique of ultraviolet and visible spectroscopy is one of the most flexible tools available to the analytical chemist, with numerous practical applications across a wide range of fields. This book provides an introduction to the technique which will give newcomers to the field a good understanding of the basic principles, and a wealth of practical information. The reader is first carefully introduced to the basics of the technique, and some of the key instrumentation used, while later chapters consider both quantitative and qualitative aspects. Highly practical information is given in the chapter on spectroscopic determinations, while there is also a chapter devoted to derivative spectroscopy. This second edition of Ultraviolet and Visible Spectroscopy will prove invaluable to all those studying and using this technique for the first time. Self-assessment questions allow readers to progress through the book confident that they are acquiring the knowledge to enable them to make effective use of this technique in the laboratory. Analytical Chemistry by Open Learning This series provides a uniquely comprehensive and integrated coverage of analytical chemistry, covering basic concepts, classical methods, instrumental techniques and applications. The learning objectives of each text are clearly identified and the student’s understanding of the material is constantly challenged by self-assessment questions with reinforcing or remedial responses. The overall objective of Analytical Chemistry by Open Learning is to enable the student to select and apply appropriate methods and techniques to solve analytical problems, and to interpret the results obtained.

Laser-enhanced ionization (LEI) is a type of optical spectrometry that employs photoexcitation to ionize atoms selectively. Over the past two decades, this method--originally known as the optogalvanic effect--has been the object of extensive worldwide research and the subject of numerous papers and published articles. Until now, however, no single volume has presented this wealth of theory and data in a cohesive and accessible form.
Laser-Enhanced Ionization Spectrometry fills this gap in the literature. It synthesizes vast amounts of information previously available only through scattered research papers and covers every aspect of the technology, from underlying principles and theory to methodology and applications. This book examines the state of the art of LEI, compares it with other methods, and demonstrates how laser-enhanced collisional ionization is especially well suited to analytical atomic spectrometry.
The contributors to this collaborative effort--from Russia, Australia, Europe, and the United States--clarify terminology, explain the inner workings of LEI, and offer derivations for both idealized forms and realistic approximations. They also analyze the capabilities and limitations of this technique as an analytical method, including instrumentation, sources of noise, limits of detection, interferences, and applications.
After concentrating largely on flame LEI as the most commonly used method to derive LEI measurements, the discussion moves to the development of nonflame technologies for LEI. There is also extended coverage of the relationship between LEI and laser-induced fluorescence, including an examination of the interplay of laser-induced ionization and fluorescence techniques in different atomic and molecular reservoirs.
Laser-Enhanced Ionization Spectrometry places understanding, usefulness, and practical applications ahead of detailed derivations. For practicing analytical chemists and spectroscopists, it offers a clear and uncluttered approach to a complex subject, as well as a fresh perspective on a still-emerging technology.
This book sums up the present understanding and state of the art of laser-enhanced ionization (LEI)-a unique but underutilized tool for analytical atomic spectrometry. LEI possesses the special ability to ionize atoms selectively. The text focuses on the role of this technology in analytical chemistry, and covers both theory and applications in one complete, self-contained volume.
Carefully crafted by leading experts from around the globe, with contributions under six key headings, Laser-Enhanced Ionization Spectrometry
* Draws on hundreds of research papers to create a comprehensive reference for LEI
* Describes in depth how ions are produced, and how a signal is generated and detected
* Provides an extensive and up-to-date compilation of published LEI detection limits
* Emphasizes basic understanding and practical applications rather than detailed derivations
* Discusses terms and definitions and clears up sources of confusion in the field
* Offers up-to-date coverage of instrumentation and applications
* Evaluates the usefulness of LEI as an analytical tool
* Deals with questions of limits of detection, interference, and noise
* Devotes an entire segment to nonflame technologies for LEI
* Extends the discussion to fluorescence techniques and how they can be interrelated with LEI in various atomic and molecular reservoirs

About this book— In recent years, a number of different spectroscopic techniques have been applied to the study of a wide range of biomedical topics. Biomedical investigations in fields as diverse as eye lens research, the study of cardiovascular and inflammatory diseases, and the study of oxidative stress in disease can now be carried out by spectroscopic means. The nine chapters in Biomedical Applications of Spectroscopy present an authoritative overview of the current status of the field, with each chapter written by acknowledged experts. A wide range of techniques is considered, including optical microspectroscopy, Raman spectroscopy, FTIR spectroscopy, NMR and EPR spectroscopy and mass spectrometry. This highly topical volume will stimulate interest in this expanding field, and point the way towards future directions in research. The major objectives of this established series are to integrate theory and practice and to bring together different branches of both academic and industrial research through the presentation of critical review articles in fundamental and applied spectroscopy. The policy of the editors is to commission authoritative reviews by acknowledged leaders in the various fields of spectroscopy. Thus each volume presents a carefully composed picture of the ‘state of the art’ for a particular area. For each volume the subject matter is presented in a manner which is Comprehensible to the non-expert, for whom the series will continue to provide a valuable introduction, and a timely overview of topics in spectroscopy which are of current interest and importance. At the same time the involved expert will find much to engage his or her attention. The series is of interest to research scientists and technologists, to teachers and both graduate and undergraduate students.

The manner in which polymers are linked, under certain conditions, forms the main focus of this work. Spectroscopy has, over the years, proved itself to be the technique in providing information at molecular levels for many polymer systems. This book provides an overview of the current state-of-the-art through contributions by world-renowned experts. Techniques covered include: ?1H and ?13C NMR; NMR Imaging, Solid State NMR, Infra Red and Raman spectroscopy, ESR, light and neutron scattering. The book will be invaluable to post graduate students of polymer science and researchers using any one of the many spectroscopic techniques.

This two-volume book provides an enriching insight into the laser, covering different types of lasers, the basic science behind the technology, their role at the cutting-edge of current scientific research, and their wide-ranging applications. With just high school physics as a prerequisite and favoring qualitative yet scientifically sound explanations over high-level mathematics, this book is aimed at a broad spectrum of readers in physics, chemistry, engineering, medicine, and biology. Its engaging and lucid presentation is enhanced with plenty of illustrations, making the world of the laser accessible to undergraduate students in the sciences and any other inquisitive readers with high school physics under their belts. Furthermore, the text is often laced with anecdotes, picked from history, that are bound to pique the minds of the readers. It is ideal for self-study or as a complement to courses on optics and optoelectronics.  This volume, Part 1 of 2, explains the fundamentals of optics, what a laser is, how it works, and what is unique about the light it emits, from fundamental quantum theory through population inversion and cavity to common laser types.  It is followed by Part 2 which depicts the many advances in science enabled by the laser, including spectroscopy, nonlinear optics, optical cooling and trapping, and optical tweezers, among many others, and provides a glimpse into the ways that the laser affects our lives via its uses in medicine, manufacturing, the nuclear industry, energy, defence, communication, ranging, pollution monitoring, art conservation, fashion, beauty, and entertainment.

This is a methods-oriented book, which contains enormous amounts of information on 31P NMR, in a concise and well-edited format. It is an invaluable resource for every NMR spectroscopist.
This book consists of 33 chapters, which together 'constitute a compendium that will be of optimal utility to the majority of 31P NMR spectroscopy users as well as to those perhaps not as familiar with the technique but curious about potential applications in their own research.' (From the editors' preface)
There have been a number of new developments in NMR techniques in the 6 years since Verkade and Quin edited the first, successful book on 31P NMR. This new book does not supersede the previous book; it offers a wide cross-section of recent research. Compard to the first, basic, grounding volume, this book presents more results (it is more applied); it directly reflects a more mature science.
Arguably, VCH has published the best NMR books in recent years (Neuhaus/Williamson, Croasmun/Carlson, etc.). This new addition to VCH's NMR list ensures the continued visibility and excellence of VCH in this field.

The past decade has seen huge advances in the types and applications of mass spectrometry in all areas of science. With this growth has come a bewildering array of names, technical terms and abbreviations, making it a challenge to keep up-to-date.

This Dictionary is a starting point for all those new to the topic, as well as a useful reference on terminology for those already in the field. Fully illustrated in full colour, the Dictionary will aid scientists from all disciplines in becoming conversant in the language and terminology of mass spectrometry.

The Dictionary will be an essential reference source for: experienced users as an aide memoir or when seeking clarification of terminologypurchasers of equipment who need an explanation of the technical terms used in manufacturer's brochures and manualspotential MS users who want a definition of an unfamiliar instrument or technique.

Annual Reports on NMR Spectroscopy, Volume 97, provides an in-depth accounting of progress in nuclear magnetic resonance (NMR) spectroscopy and its many applications. In recent years, no other technique has gained as much significance. It is used in all branches of science in which precise structural determination is required, and in which the nature of interactions and reactions in solution is being studied. This book has established itself as a premier resource for both specialists and non-specialists who are looking to become familiar with new techniques and applications pertaining to NMR spectroscopy.

Polymer Surfaces and Interfaces II W. J. Feast, University of Durham, Durham, UK H. S. Munro, Courtaulds Research, Coventry, UK R. W. Richards, University of Durham, Durham, UK This volume presents a collection of review papers, based on the a Polymer Surfaces and Interfaces II International Symposiuma which took place in Durham (UK), July 1991 Compiled here, the papers present an authoritative overview of current technology and research on polymer surfaces, by acknowledged experts in their specialist fields. Individual reviews cover analytical techniques, properties, reactions, modelling and synthesis of surfaces and interfaces. Polymer Surfaces and Interfaces II will be of interest to polymer scientists, surface scientists, chemists, physicists and biologists, working in industrial and academic laboratories. Reviews of the previous volume a Altogether a most useful addition to polymer sciencea ---- Physics Bulletin a The book can be unreservedly recommended to chemists and materials scientists with an interest in adhesion, biomaterials, polymer dispersions and molecular engineeringa ---- Polymer Contents Surface Chemistry of Chemically Resistant Polymers; T. G. Bee, A. J. Dias, N. L. Franchina, B. U. Kolb, K.--W. Lee, P. A. Patton, M. S. Shoichet and T. J. McCarthy Self--assembled Molecular Films as Polymer Surface Models; D. L. Allara, S. V. Atre and A. N. Parikh Non--equilibrium Effects in Polymeric Stabilization; M. E. Cates and J. T. Brooks Ion Beam Analysis of Composition Profiles near Polymer Surfaces and Interfaces; R. A. L. Jones Laser Light Scattering; J. C. Earnshaw Characterization of Interfaces in Polymers and Composites using Raman Spectroscopy; R. J. Young Surface Modification and Analysis of Ultra--high--modulus Polyethylene Fibres for Composites; G. A. George SSIMS ---- An Emeriging Technique for the Surface Chemical Analysis of Polymeric Biomaterials; M. C. Davies Scanning Probe Microscopy ---- Current Issues in the Analysis of Polymeric Biomaterials; M. C. Davies, D. E. Jackson, C. J Roberts, S. J. B. Tendler, K. M. Kreusel, M. J. Wilkins and P. M. Williams Surface Grafting of a Thrombin Substrate on a Polymer Membrane and the Inhibition of Thrombin Activity Leading to Non--thrombogenicity; Y. Ito, L.--S. Liu and Y. Imanishi Acid----Base Effects at Polymer Interfaces; C. J. van Oss

Michael Hollas’s classic text Modern Spectroscopy has long been a bible for undergraduates studying spectroscopy. Now, Wiley is delighted to announce its big brother, the second edition of High Resolution Spectroscopy. High Resolution Spectroscopy is aimed in particular at graduates continuing their studies in spectroscopy. It follows and broadens the topics of Modern Spectroscopy, taking the subject to the frontiers of research. The second edition includes a greatly expanded chapter on lasers and laser spectroscopy to reflect developments in this field during the past 20 years. As in Modern Spectroscopy, Michael Hollas writes in an extremely clear fashion and manages to make even complicated topics easy to understand. Features include:

• 560 diagrams
• Over 100 tables
• 570 references
• Greatly expanded chapter on lasers and laser spectroscopy

Solid State Physics: An Introduction to Theory presents an intermediate quantum approach to the properties of solids. Through this lens, the text explores different properties, such as lattice, electronic, elastic, thermal, dielectric, magnetic, semiconducting, superconducting and optical and transport properties, along with the structure of crystalline solids. The work presents the general theory for most of the properties of crystalline solids, along with the results for one-, two- and three-dimensional solids in particular cases. It also includes a brief description of emerging topics, such as the quantum hall effect and high superconductivity. Building from fundamental principles and requiring only a minimal mathematical background, the book includes illustrative images and solved problems in all chapters to support student understanding.

Ion Mobility Spectrometry, Volume 83 will focuses on new trends, methods and instrumentation in the field, starting from the innovations of each technique, to the most progressive challenges of IM-MS. Chapters includes section on Recent advances in IM-MS, IM-MS Principles and Theory, IM-MS Applications and Instrumentation, and the Future of IM-MS.

Terahertz time-domain spectroscopy (THz-TDS) is a unique technique for characterizing the response of materials and devices in the far-infrared region of the electromagnetic spectrum. Based on the measurement of transmitted or reflected ultra-short electromagnetic pulses and on a Fourier-transform of the recorded waveforms, THz-TDS permits fast and precise determination of the permittivity or permeability of materials over a wide bandwidth. This book is devoted to the determination of this spectral response of samples from the recorded waveforms.

Providing a definitive reference source on novel methods in NMR acquisition and processing, this book will highlight similarities and differences between emerging approaches and focus on identifying which methods are best suited for different applications. The highly qualified editors have conducted extensive research into the fundamentals of fast methods of data acquisition in NMR, including applications of non-Fourier methods of spectrum analysis. With contributions from additional distinguished experts in allied fields, clear explanations are provided on methods that speed up NMR experiments using different ways to manipulate the nuclei in the sample, modern methods for estimating the spectrum from the time domain response recorded during an NMR experiment, and finally how the data is sampled. Starting with a historical overview of Fourier Transformation and its role in modern NMR spectroscopy, this volume will clarify and demystify this important emerging field for spectroscopists and analytical chemists in industry and academia.

Computational Optical Biomedical Spectroscopy and Imaging covers recent discoveries and research in the field by some of the best inventors and researchers in the world. It also presents useful computational methods and applications used in optical biomedical spectroscopy and imaging. Topics covered include: New trends in immunohistochemical, genome, and metabolomics imaging Computer-aided diagnosis of interstitial lung diseases based on CT image analysis Functional near-infrared spectroscopy and its applications in neurosciences Applications of vibrational spectroscopic imaging in personal care studies Induced optical natural fluorescence spectroscopy for Giardia lamblia cysts Nanoimaging and polarimetric exploratory data analysis Fluorescence bioimaging with applications to chemistry Medical imaging instrumentation and techniques The book also discusses future applications, directions, opportunities, and challenges of optical biomedical spectroscopy and imaging in technical industry, academia, and government. This valuable resource introduces key concepts of computational methods used in optical biomedical spectroscopy and imaging in a manner that is easily understandable to beginners and experts alike.

With the increasing role of porous solids in conventional and newly emerging technologies, there is an urgent need for a deeper understanding of fluid behaviour confined to pore spaces of these materials especially with regard to their transport properties. From its early years, NMR has been recognized as a powerful experimental technique enabling direct access to this information. In the last two decades, the methodological development of different NMR techniques to assess dynamic properties of adsorbed ensembles has been progressed. This book will report on these recent advances and look at new broader applications in engineering and medicine. Having both academic and industrial relevance, this unique reference will be for specialists working in the research areas and for advanced graduate and postgraduate studies who want information on the versatility of diffusion NMR.

Annual Reports on NMR Spectroscopy, Volume 93 provides a thorough and in-depth accounting of progress in nuclear magnetic resonance (NMR) spectroscopy and its many applications. This updated volume in this premier resource for both specialists and non-specialists focuses on NMR at Giga-Pascal Pressures, Ultrafast 2D NMR: Methods and Applications, Perspective on the Hyperpolarization Technique Signal Amplification by Reversible Exchange (SABRE) in NMR Spectroscopy and MR Imaging, and Recent Advances in 11B Solid-State Nuclear Magnetic Resonance Spectroscopy of Crystalline Solids, and Progress in Our Understanding of 19F Chemical Shifts, amongst other timely topics.

It is estimated that there are about 10 million organic chemicals known, and about 100,000 new organic compounds are produced each year. Some of these new chemicals are made in the laboratory and some are isolated from natural products. The structural determination of these compounds is the job of the chemist. There are several instrumental techniques used to determine the structures of organic compounds. These include NMR, UV/visible, infrared spectroscopy, mass spectrometry, and X-ray crystallography. Of all the instrumental techniques listed, infrared spectroscopy and mass spectrometry are the two most popular techniques, mainly because they tend to be less expensive and give us the most structural information. This book is an introductory text designed to acquaint undergraduate and graduate students with the basic theory and interpretative techniques of infrared spectroscopy. Much of the material in this text has been used over a period of several years for teaching courses in materials characterization and chemical analysis. It presents the infrared spectra of the major classes of organic compounds and correlates the infrared bands (bond vibrations) of each spectrum with the structural features of the compound it represents. This has been done for hydrocarbons, organic acids, ketones, aldehydes, esters, anhydrides, phenols, amines, and amides. The text discusses the origin of the fragments, techniques, innovations, and applications in infrared spectroscopy. It is interspersed with many illustrations, examples, an adequate but not overwhelming bibliography, and problems for students. It will serve as a lecture text for a one-semester course in infrared spectroscopy or can be used to teach the infrared spectroscopy portion of a broader course in material characterization and chemical analysis.

Applications of Mass Spectrometry Imaging to Cancer, the latest volume in the Advances in Cancer Research provides invaluable information on the exciting and fast-moving field of cancer research. This volume presents original reviews on applications of mass spectrometry imaging to cancer.

Annual Reports on NMR Spectroscopy provides a thorough and in-depth accounting of progress in nuclear magnetic resonance (NMR) spectroscopy and its many applications. Nuclear magnetic resonance (NMR) is an analytical tool used by chemists and physicists to study the structure and dynamics of molecules. In recent years, no other technique has gained as much significance as NMR spectroscopy. It is used in all branches of science in which precise structural determination is required, and where the nature of interactions and reactions in solution is being studied. This book has established itself as a premier means for both specialists and non-specialists looking to familiarize themselves with the newest techniques and applications pertaining to NMR spectroscopy.

Applications of High Resolution Mass Spectrometry: Food Safety and Pesticide Residue Analysis is the first book to offer complete coverage of all aspects of high resolution mass spectrometry (HRMS) used for the analysis of pesticide residue in food. Aimed at researchers and graduate students in food safety, toxicology, and analytical chemistry, the book equips readers with foundational knowledge of HRMS, including established and state-of-the-art principles and analysis strategies. Additionally, it provides a roadmap for implementation, including discussions of the latest instrumentation and software available. Detailed coverage is given to the application of HRMS coupled to ultra high-performance liquid chromatography (UHPLC-HRMS) in the analysis of pesticide residue in fruits and vegetables and food from animal origin. The book also discusses extraction procedures and the challenges of sample preparation, gas chromatography coupled to high resolution mass spectrometry, flow injection-HRMS, ambient ionization, and identification of pesticide transformation products in food. Responding to the fast development and application of these new procedures, this book is an essential resource in the food safety field.

Membrane Characterization provides a valuable source of information on how membranes are characterized, an extremely limited field that is confined to only brief descriptions in various technical papers available online. For the first time, readers will be able to understand the importance of membrane characterization, the techniques required, and the fundamental theory behind them. This book focuses on characterization techniques that are normally used for membranes prepared from polymeric, ceramic, and composite materials.

In situ Spectroscopic Techniques at High Pressure provides a comprehensive treatment of in-situ applications of spectroscopic techniques at high pressure and their working principles, allowing the reader to develop a deep understanding of which measurements are accessible with each technique, what their limitations are, and for which application each technique is best suited. Coverage is also given to the instrumental requirements for these applications, with respect to the high pressure instrumentation and the spectroscopic components of the equipment. The pedagogical style of the book is supplemented by the inclusion of "study questions" which aim to make it useful for graduate-level courses.