Physical Methods in Chemical Analysis, Volume IV focuses on the application of physical methods in chemical analysis, including dialysis, chromatography, electromagnetic separations, and thermal diffusion. The selection first offers information on dialysis and separations with molecular sieves and foams. Topics include membranes for dialysis, apparatus and techniques, application of molecular sieves to the problems of separation, adsorption measurements and techniques, and molecular sieve adsorbents. The text then elaborates on separations with foams and electromagnetic separations. The publication explains ion exchange and analytical applications of inclusion. Discussions focus on separations by ion-exchange chromatography, general properties of ion-exchange resins, ion exclusion, and methods and technical details. The publication then ponders on separation of gases and liquids by thermal diffusion and solvent extraction. The selection is highly recommended for readers interested in the application of physical methods in chemical analysis.

Physical Methods in Modern Chemical Analysis, Volume 1 presents the fundamental principles, the instrumentation or necessary equipment, and applications of selected physical methodologies in chemical analysis. This volume contains chapters on gas chromatography; principles and instrumentation of mass spectrometry; fluorescence and atomic absorption spectroscopy; applications, scope, and structural problems of mass spectrometry; and flame and plasma emission methods of analysis. Chemists, researchers, and students of chemistry will find the book an excellent reference material.

Physical Methods in Chemical Analysis, Volume II discusses analytical procedures that deal primarily with nonchemical methods and techniques useful in establishing the qualitative nature of unknowns. This book discusses electrical, magnetic, and miscellaneous techniques, including a number of methods that only measure non-specific properties to obtain quantitative information on relatively simple systems such as conductometric titration and radioactive tracer methods. This volume emphasizes two major tasks that analysts need to do in order to perform analysis. First is to conduct preliminary operations that bring the system under investigation into physical states suitable for analysis. Second is to measure physical constants that can be compared with known systems for identity or can be interpreted in terms of structure and organization. This publication is a recommended reference for students and chemists working on chemical analysis.

Selection of the HPLC Method in Chemical Analysis serves as a practical guide to users of high-performance liquid chromatography and provides criteria for method selection, development, and validation. High-performance liquid chromatography (HPLC) is the most common analytical technique currently practiced in chemistry. However, the process of finding the appropriate information for a particular analytical project requires significant effort and pre-existent knowledge in the field. Further, sorting through the wealth of published data and literature takes both time and effort away from the critical aspects of HPLC method selection. For the first time, a systematic approach for sorting through the available information and reviewing critically the up-to-date progress in HPLC for selecting a specific analysis is available in a single book. Selection of the HPLC Method in Chemical Analysis is an inclusive go-to reference for HPLC method selection, development, and validation. - Addresses the various aspects of practice and instrumentation needed to obtain reliable HPLC analysis results - Leads researchers to the best choice of an HPLC method from the overabundance of information existent in the field - Provides criteria for HPLC method selection, development, and validation - Authored by world-renowned HPLC experts who have more than 60 years of combined experience in the field

Physical Methods in Modern Chemical Analysis, Volume 2 covers the fundamental principles, the instrumentation or necessary equipment, and applications of selected physical methods. This volume contains five chapters, and deals first with the theory, instrumentation, column features, and applications of high-performance liquid chromatography. The next two chapters survey the principles, experimental aspects, procedures, and specific applications of X-ray photoelectron spectroscopy and X-ray diffraction methods. A chapter discusses the technical and theoretical aspects of ion cyclotron resonance, with a special emphasis on its application in gas phase ion and neutral compounds analysis. The last chapter explores the apparatus and experimental procedures in refractive index measurements. This book will be of value to analytical chemists and analytical chemistry researchers.