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Preface

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    This book is intended to accompany an introductory course on non-relativistic quantum mechanics. Some previous knowledge of physics and mathematics is assumed. In particular, readers need to be reasonably familiar with Newtonian dynamics, elementary classical electromagnetism and special relativity, the physics and mathematics of waves (including the representation of waves via complex functions), basic probability theory, ordinary and partial differential equations, linear algebra, vector algebra, and Fourier series and transforms.

    The aim of this book is to develop non-relativistic quantum mechanics as a complete theory of microscopic dynamics, capable of making detailed predictions, with a minimum of abstract mathematics.

    The first part of the book is devoted to an in-depth exploration of the basic principles of quantum mechanics. After a brief review of probability theory, in Chapter 1, the book starts, in Chapter 2, by examining how many of the central ideas of quantum mechanics are a direct consequence of wave-particle duality---that is, the concept that waves sometimes act as particles, and particles as waves. The book then proceeds to investigate the rules of quantum mechanics in a more systematic fashion in Chapter 3. Quantum mechanics is used to examine the motion of a single particle in one dimension, many particles in one dimension, and a single particle in three dimensions, in Chapters 4, 5, and 6, respectively. Chapter 7 is devoted to the investigation of orbital angular momentum, and Chapter 8 to the closely related subject of particle motion in a central potential. Finally, in Chapters 9 and 10, the book considers spin angular momentum, and the addition of orbital and spin angular momenta, respectively.

    The second part of the book describes selected practical applications of quantum mechanics. In Chapter 11, time-independent perturbation theory is used to investigate the Stark effect, the Zeeman effect, fine structure, and hyperfine structure, in the hydrogen atom. Time-dependent perturbation theory is then employed to study radiative transitions in the hydrogen atom in Chapter 12. Chapter 13 illustrates the use of variational methods in quantum mechanics. Finally, Chapter 14 contains an introduction to quantum scattering theory.