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Quantum Chemistry &Spectroscopy
ISBN: 9780321615046 | 0321615042
Edition: 2ndFormat: Hardcover
Publisher: Prentice Hall
Pub. Date: 4/17/2009
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For courses in Quantum Chemistry. This full-color, modern physical chemistry text offers arresting illustrations that set it apart from others of its kind. The authors focus on core topics of physical chemistry, presented within a modern framework of applications. Extensive math derivations are provided, yet the book retains the significant chemical rigor needed in physical chemistry.
This full-color, modern physical chemistry reference offers compelling applications and arresting illustrations that capture readers... MORE
This full-color, modern physical chemistry reference offers compelling applications and arresting illustrations that capture readers... MORE
| From Classical to Quantum Mechanics | |
| Why Study Quantum Mechanics? | |
| Quantum Mechanics Arose Out of the Interplay of Experiments and Theory | |
| Blackbody Radiation | |
| The Photoelectric Effect | |
| Particles Exhibit Wave-Like Behavior | |
| Diffraction by a Double Slit | |
| Atomic Spectra and the Bohr Model for the Hydrogen Atom | |
| The Schrodinger Equation... MORE | |
| What Determines If a System Needs to Be Described Using Quantum Mechanics? | |
| Classical Waves and the Nondispersive Wave Equation | |
| Waves Are Conveniently Represented as Complex Functions | |
| Quantum Mechanical Waves and the Schrodinger Equation | |
| Solving the Schrodinger Equation: Operators, Observables, Eigenfunctions, and Eigenvalues | |
| The Eigenfunctions of a Quantum Mechanical Operator Are Orthogonal | |
| The Eigenfunctions of a Quantum Mechanical Operator Form a Complete Set | |
| Summing Up the New Concepts | |
| The Quantum Mechanical Postulates | |
| The Physical Meaning Associated with the Wave Function | |
| Every Observable Has a Corresponding Operator | |
| The Result of an Individual Measurement | |
| The Expectation Value | |
| The Evolution in Time of a Quantum Mechanical System | |
| Using Quantum Mechanics on Simple Systems | |
| The Free Particle | |
| The Particle in a One-Dimensional Box | |
| Two- and Three-Dimensional Boxes | |
| Using the Postulates to Understand the Particle in the Box and Vice Versa | |
| The Particle in the Box and the Real World | |
| The Particle in the Finite Depth Box | |
| Differences in Overlap between Core and Valence Electrons | |
| Pi Electrons in Conjugated Molecules Can Be Treated as Moving Freely in a Box | |
| Why Does Sodium Conduct Electricity and Why Is Diamond an Insulator? | |
| Tunneling through a Barrier | |
| The Scanning Tunneling Microscope | |
| Tunneling in Chemical Reactions 5.8 | |
| (Supplemental) Quantum Wells and Quantum Dots | |
| Commuting and Noncommuting Operators and the Surprising Consequences of Entanglement | |
| Commutation Relations | |
| The Stern-Gerlach Experiment | |
| The Heisenberg Uncertainty Principle | |
| (Supplemental) The Heisenberg Uncertainty Principle Expressed in Terms of Standard Deviations | |
| (Supplemental) A Thought Experiment Using a Particle in a Three-Dimensional Box | |
| (Supplemental) Entangled States, Teleportation, and Quantum Computers | |
| A Quantum Mechanical Model for the Vibration and Rotation of Molecules | |
| Solving the Schrodinger Equation for the Quantum Mechanical Harmonic Oscillator | |
| Solving the Schrodinger Equation for Rotation in Two Dimensions | |
| Solving the Schrodinger Equation for Rotation in Three Dimensions | |
| The Quantization of Angular Momentum | |
| The Spherical Harmonic Functions | |
| (Optional Review) The Classical Harmonic Oscillator | |
| (Optional Review) Angular Motion and the Classical Rigid Rotor | |
| (Supplemental) Spatial Quantization | |
| The Vibrational and Rotational Spectroscopy of Diatomic Molecu | |
| Table of Contents provided by Publisher. All Rights Reserved. |
Thomas Engel has taught chemistry for more than 20 years at the University of Washington, where he is currently Professor of Chemistry and Associate Chair for the Undergraduate Program. Professor Engel received his bachelor's and master's degrees in chemistry from the Johns Hopkins University, and his Ph.D. in chemistry from the University of Chicago. He then spent 11 years as a researcher in Germany and Switzerland, in which time he received the Dr. rer. nat. habil. degree from the Ludwig Maximilians University in Munich. In 1980, he left the IBM research laboratory in Zurich to become a faculty member at the University of Washington.
Professor Engel's research interests are in the area of surface chemistry, and he has published more than 80 articles and book chapters in this field. He has received the Surface Chemistry or Colloids Award from the American Chemical Society and a Senior Humboldt Research Award from the Alexander von Humboldt Foundation, which has allowed him to establish collaborations with researchers in Germany. He is currently working together with European manufacturers of catalytic converters to improve their performance for diesel engines.
Philip Reid has taught chemistry at the University of Washington since he joined the chemistry faculty in 1995. Professor Reid received his bachelor's degree from the University of Puget Sound in 1986, and his Ph.D. in chemistry from the University of California at Berkeley in 1992. He performed postdoctoral research at the University of Minnesota, Twin Cities, campus before moving to Washington.
Professor Reid's research interests are in the areas of atmosphere chemistry, condensed-phase reaction dynamics, and nonlinear optical materials. He has published more than 70 articles in these fields. Professor Reid is the recipient of a CAREER award from the National Science Foundation, is a Cottrell Scholar of the Research Corporation, and is a Sloan fellow.
Professor Engel's research interests are in the area of surface chemistry, and he has published more than 80 articles and book chapters in this field. He has received the Surface Chemistry or Colloids Award from the American Chemical Society and a Senior Humboldt Research Award from the Alexander von Humboldt Foundation, which has allowed him to establish collaborations with researchers in Germany. He is currently working together with European manufacturers of catalytic converters to improve their performance for diesel engines.
Philip Reid has taught chemistry at the University of Washington since he joined the chemistry faculty in 1995. Professor Reid received his bachelor's degree from the University of Puget Sound in 1986, and his Ph.D. in chemistry from the University of California at Berkeley in 1992. He performed postdoctoral research at the University of Minnesota, Twin Cities, campus before moving to Washington.
Professor Reid's research interests are in the areas of atmosphere chemistry, condensed-phase reaction dynamics, and nonlinear optical materials. He has published more than 70 articles in these fields. Professor Reid is the recipient of a CAREER award from the National Science Foundation, is a Cottrell Scholar of the Research Corporation, and is a Sloan fellow.
