A First Introduction to Quantum Physics / by Pieter Kok.

Format:

Book

Author/Creator:

Kok, Pieter, Author.

Series:

Undergraduate Lecture Notes in Physics, 2192-4791

Language:

English

Subjects (All):

Quantum theory.

Physics.

Quantum field theory.

String models.

Mathematical physics.

Quantum Physics.

Mathematical Methods in Physics.

Quantum Field Theories, String Theory.

Mathematical Applications in the Physical Sciences.

Local Subjects:

Quantum Physics.

Mathematical Methods in Physics.

Quantum Field Theories, String Theory.

Mathematical Applications in the Physical Sciences.

Physical Description:

1 online resource (IX, 243 p. 63 illus., 2 illus. in color.)

Edition:

1st ed. 2018.

Place of Publication:

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

Summary:

In this undergraduate textbook, the author develops the quantum theory from first principles based on very simple experiments: a photon travelling through beam splitters to detectors, an electron moving through a Stern-Gerlach machine, and an atom emitting radiation. From the physical description of these experiments follows a natural mathematical description in terms of matrices and complex numbers. The first part of the book examines how experimental facts force us to let go of some deeply held preconceptions and develops this idea into a mathematical description of states, probabilities, observables, and time evolution using physical applications. The second part of the book explores more advanced topics, including the concept of entanglement, the process of decoherence, and extension of the quantum theory to the situation of a particle in a one-dimensional box. Here, the text makes contact with more traditional treatments of quantum mechanics. The remaining chapters delve deeply into the idea of uncertainty relations and explore what the quantum theory says about the nature of reality. The book is an ideal and accessible introduction to quantum physics, with modern examples and helpful end-of-chapter exercises.

Contents:

Chapter 1: Three simple experiments

The purpose of physical theories

A laser and a detector

A laser and a beam splitter

A Mach-Zehnder interferometer

The breakdown of classical concepts

Chapter 2: Photons and Interference

Photon paths and superpositions

The beam splitter as a matrix

The phase in an interferometer

How to calculate probabilities

Gravitational wave detection

Chapter 3: Electrons with Spin

The Stern-Gerlach experiment

The spin observable

The Bloch sphere

The uncertainty principle

Magnetic resonance imaging

Chapter 4: Atoms and Energy

The energy spectrum of atoms

Changes over time

The Hamiltonian

Interactions

Atomic clocks

Chapter 5: Operators

Eigenvalue problems

Observables

Evolution

The commutator

Projectors

Chapter 6: Entanglement

The state of two electrons

Entanglement

Quantum teleportation

Quantum computers

Chapter 7: Decoherence

Classical and quantum uncertainty

The density matrix

Interactions with the environment

Entropy and Landauer’s principle

Chapter 8: The Motion of Particles

A particle in a box

The momentum of a particle

The energy of a particle

The scanning tunneling microscope

Chemistry

Chapter 9: Uncertainty Relations

Quantum uncertainty revisited

Position-momentum uncertainty

The energy-time uncertainty relation

The quantum mechanical pendulum

Precision measurements

Chapter 10: The Nature of Reality

The emergent classical world

The quantum state revisited

Nonlocality

Contextuality

A compendium of interpretations.

ISBN:

3-319-92207-6