Judul : Quantum Mechanics, Demystified (A Self-Teaching Guide)
Pengarang
: David McMahon
Penerbit
: McGraw-Hill
PREFACE
Quantum
mechanics, which by its very nature is highly mathematical (and therefore extremely
abstract), is one of the most difficult areas of physics to master. In these pages
we hope to help pierce the veil of obscurity by demonstrating, with explicit examples,
how to do quantum mechanics. This book is divided into three main parts.
After a
brief historical review, we cover the basics of quantum theory from the perspective
of wave mechanics. This includes a discussion of the wave function, the
probability interpretation, operators, and the Schrödinger equation. We then consider
simple one-dimensional scattering and bound state problems.
In the
second part of the book we cover the mathematical foundations needed to do
quantum mechanics from a more modern perspective. We review the necessary elements
of matrix mechanics and linear algebra, such as finding eigenvalues and eigenvectors,
computing the trace of a matrix, and finding out if a matrix is Hermitian or
unitary. We then cover Dirac notation and Hilbert spaces. The postulates of
quantum mechanics are then formalized and illustrated with examples. In the chapters
that cover these topics, we attempt to “demystify” quantum mechanics by providing
a large number of solved examples.
The final
part of the book provides an illustration of the mathematical foundations of
quantum theory with three important cases that are typically taught in a first semester
course: angular momentum and spin, the harmonic oscillator, and an introduction
to the physics of the hydrogen atom. Other topics covered at some level with
examples include the density operator, the Bloch vector, and two-state systems.
Unfortunately,
due to the large amount of space that explicitly solved examples from quantum
mechanics require, it is not possible to include everything about the theory in
a volume of this size. As a result we hope to prepare a second volume to cover
advanced topics from non-relativistic quantum theory such as scattering, identical
particles, addition of angular momentum, higher Z atoms, and the WKB approximation.
There is no
getting around the mathematical background necessary to learn quantum
mechanics. The reader should know calculus, how to solve ordinary and partial
differential equations, and have some exposure to matrices/linear algebra and
at least a basic working knowledge of complex numbers and vectors. Some knowledge
of basic probability is also helpful. While this mathematical background is
extensive, it is our hope that the book will help “demystify” quantum theory
for those who are interested in self-study or for those from different
backgrounds such as chemistry, computer science, or engineering, who would like
to learn something about quantum mechanics.
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