1.

Record Nr.

UNINA9910300555503321

Autore

Deych Lev I

Titolo

Advanced Undergraduate Quantum Mechanics : Methods and Applications / / by Lev I. Deych

Pubbl/distr/stampa

Cham : , : Springer International Publishing : , : Imprint : Springer, , 2018

ISBN

3-319-71550-X

Edizione

[1st ed. 2018.]

Descrizione fisica

1 online resource (XIX, 610 p. 50 illus., 26 illus. in color.)

Disciplina

530.12

Soggetti

Quantum physics

Mathematical physics

Quantum optics

Physics

Chemistry, Physical and theoretical

Applied mathematics

Engineering mathematics

Quantum Physics

Mathematical Applications in the Physical Sciences

Quantum Optics

Mathematical Methods in Physics

Theoretical and Computational Chemistry

Mathematical and Computational Engineering

Lingua di pubblicazione

Inglese

Formato

Materiale a stampa

Livello bibliografico

Monografia

Note generali

Includes index.

Nota di contenuto

Dedication -- Preface -- Part I Language and Formalism of Quantum Mechanics -- 1 Introduction -- 2 Quantum States -- 3 Observables and Operators -- 4 Unitary Operators and Quantum Dynamics -- 5 Representations of Vectors and Operators -- Part II Quantum Models -- 6 One-Dimensional Models -- 7 Harmonic Oscillator Models -- 8 Hydrogen Atom -- 9 Spin 1/2 -- 10 Two-Level System in a Periodic External Field -- 11 Non-Interacting Many-Particle Systems -- Part III Quantum Phenomena and Methods -- 12 Resonant Tunneling -- 13 Peturbation Theory for Stationary States: Stark Effect and Polarization of



Atoms -- 14 Fine Structure of the Hydrogen Spectra and Zeeman Effect -- 15 Emission and Absorption of Light -- 16 Free Electrons in Uniform Magnetic Field: Landau Levels and Quantum Hall Effect -- Index.

Sommario/riassunto

This introduction to quantum mechanics is intended for undergraduate students of physics, chemistry, and engineering with some previous exposure to quantum ideas. Following in Heisenberg’s and Dirac’s footsteps, this book is centered on the concept of the quantum state as an embodiment of all experimentally available information about a system, and its representation as a vector in an abstract Hilbert space. This conceptual framework and formalism are introduced immediately, and developed throughout the first four chapters, while the standard Schrödinger equation does not appear until Chapter 5. The book grew out of lecture notes developed by the author over fifteen years of teaching at the undergraduate level. In response to numerous requests by students, material is presented with an unprecedented level of detail in both derivation of technical results and discussion of their physical significance.  The book is written for students to enjoy reading it, rather than to use only as a source of formulas and examples. The colloquial and personal writing style makes it easier for readers to connect with the material. Additionally, readers will find short, relatable snippets about the “founding fathers” of quantum theory, their difficult historical circumstances, personal failings and triumphs, and often tragic fate. This textbook, complete with extensive original end-of-chapter exercises, is recommended for use in one- or two-semester courses for upper level undergraduate and beginning graduate students in physics, chemistry, or engineering.