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This textbook provides an accessible description of the basic concepts of atomic and molecular quantum structure, and how we probe that structure using light. The ideas described here underpin many aspects of modern science in fields such as quantum computing, astrophysics and astronomy, environmental and atmospheric chemistry, and nanotechnology, to name a few. The content of this book is appropriate for those who are new to the field, such as undergraduate students, and can also be a valuable reference for non-practitioners who are interested in the subject. There are many in-chapter examples, end-of-chapter questions, and detailed workbooks included (at the end of the book) which will help the reader practice applying the material as they make their way through the text. Accompanying master classes and tutorial videos are available on the CPPC Spectroscopy YouTube channel.
Informal, effective undergraduate-level text introduces vibrational and electronic spectroscopy, presenting applications of group theory to the interpretation of UV, visible, and infrared spectra without assuming a high level of background knowledge. 200 problems with solutions. Numerous illustrations. "A uniform and consistent treatment of the subject matter." — Journal of Chemical Education.
As quantum theory enters its second century, it is fitting to examine just how far it has come as a tool for the chemist. Beginning with Max Planck’s agonizing conclusion in 1900 that linked energy emission in discreet bundles to the resultant black-body radiation curve, a body of knowledge has developed with profound consequences in our ability to understand nature. In the early years, quantum theory was the providence of physicists and certain breeds of physical chemists. While physicists honed and refined the theory and studied atoms and their component systems, physical chemists began the foray into the study of larger, molecular systems. Quantum theory predictions of these systems were first verified through experimental spectroscopic studies in the electromagnetic spectrum (microwave, infrared and ultraviolet/visible), and, later, by nuclear magnetic resonance (NMR) spectroscopy. Over two generations these studies were hampered by two major drawbacks: lack of resolution of spectroscopic data, and the complexity of calculations. This powerful theory that promised understanding of the fundamental nature of molecules faced formidable challenges. The following example may put things in perspective for today’s chemistry faculty, college seniors or graduate students: As little as 40 years ago, force field calculations on a molecule as simple as ketene was a four to five year dissertation project.
For beginners and specialists in other fields: the Nobel Laureate's introduction to atomic spectra and their relationship to atomic structures, stressing basics in a physical, rather than mathematical, treatment. 80 illustrations.
An Introduction to Spectroscopy presents the most fundamental concepts of inorganic chemistry at a level appropriate for first year students and in a manner comprehensible to them. This is true even of 'difficult' topics such as the wave mechanical atom, symmetry elements and symmetry operations, and the ligand group orbital approach to bonding, The book contains many useful diagrams illustrating (among other things) the angular dependence of atomic wave functions the derivation of energy level diagrams for polyatomic molecules; close packed lattices and ionic crystal structures. The diagrams of the periodic variation of atomic and molecular properties, showing trends across periods and down groups simultaneously, are especially instructive. Spectroscopy is presented mainly as a tool for the elucidation of atomic and molecular structures. Each chapter begins with a clear and concise statement of "What Every First-year Student Should Know About . . ." outlining the background knowledge that the student is assumed to have from previous courses and thus pointing out what topics might need to be reviewed. There are also detailed statements of the objectives of each chapter, a number of worked examples interspersed in the text, and a comprehensive set of problems and exercises to test the student's understanding. Tables of data throughout the text and appendices at the end provide much valuable information.
Two Nobel Laureates present a systematic, comprehensive account of the theory, techniques, experimental data, and interpretation involved in the study of microwave spectroscopy. Eighteen self-contained chapters on key topics may be read individually or serially, making this volume ideal as a reference as well as a textbook. 190 tables and figures. 1955 edition.
A concise textbook bridging quantum theory and spectroscopy! Designed as a practical text, Quantum Mechanical Foundations of Molecular Spectroscopy covers the quantum mechanical fundamentals of molecular spectroscopy from the view of a professional spectroscopist, rather than a theoretician. Written by a noted expert on the topic, the book puts the emphasis on the relationship between spectroscopy and quantum mechanics, and provides the background information and derivations of the subjects needed to understand spectroscopy including: stationary energy states, transitions between these states, selection rules, and symmetry. The phenomenal growth of all forms of spectroscopy over the past eight decades has contributed enormously to our understanding of molecular structure and properties. Today spectroscopy covers a broad field including the modern magnetic resonance techniques, non-linear, laser and fiber-based spectroscopy, surface and surface-enhanced spectroscopy, pico- and femtosecond time resolved spectroscopy, and many more. This up-to-date resource discusses several forms of spectroscopy that are used in many fields of science, such as fluorescence, surface spectroscopies, linear and non-linear Raman spectroscopy and spin spectroscopy. This important text: Contains the physics and mathematics needed to understand spectroscopy Explores spectroscopic methods the are widely used in chemistry, biophysics, biology, and materials science Offers a text written by an experienced lecturer and practitioner of spectroscopic methods Includes detailed explanations and worked examples Written for chemistry, biochemistry, material sciences, and physics students, Quantum Mechanical Foundations of Molecular Spectroscopy provides an accessible text for understanding molecular spectroscopy.
This graduate-level text explains the modern in-depth approaches to the calculation of electronic structure and the properties of molecules. Largely self-contained, it features more than 150 exercises. 1989 edition.
Unusually varied problems, with detailed solutions, cover quantum mechanics, wave mechanics, angular momentum, molecular spectroscopy, scattering theory, more. 280 problems, plus 139 supplementary exercises.