Quantum Physics For Dummies E-Book

Quantum Physics For Dummies®

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Table of Contents

Cover

Title Page

Copyright

Introduction

About This Book

Foolish Assumptions

Icons Used in This Book

Beyond the Book

Where to Go from Here

Part 1: Getting Started with Quantum Physics

Chapter 1: What Is Quantum Physics, Anyway?

The Classics: Pre-Quantum Physics

What Makes Physics Quantum?

A Matter of Scale, or a Scale of Matter

Measurements and Observables: How Scientists Know Quantum Physics Is True

Chapter 2: Standing on the Shoulders of Giants: Classical Physics

Objects in Motion: Classical Mechanics

Catching the Waves

Let There Be Light: Electromagnetism

Atoms: Building Blocks of Matter

Thermodynamics: Another Hot Topic

The Games People Play: Unknowns and Uncertainties

Chapter 3: The Quantum Revolution

Being Discrete: The Trouble with Black-Body Radiation

Seeing Light as Particles

Bohr’s Atomic Model

A Dual Identity: Looking at Particles as Waves

Proof Positron? Dirac and Pair Production

You Can’t Know Everything (But You Can Figure the Odds)

A New Take on Light: Quantum Electrodynamics

Breaking Open the Atom’s Bits

Part 2: The Fundamentals: Quantum Physics Principles and Theories

Chapter 4: Quantum Mechanics: Particle States and Dualities

Quantifying by Quantum Numbers

Revisiting Wave-Particle Duality

Discovering What Antimatter Is

Chapter 5: Quantum Electrodynamics and Beyond

Quantum Field Theory: Explaining Matter and Energy

Discovering How Quantum Physics Changed the World

Looking Ahead at Quantum Computers

Chapter 6: Quantum Cats and Spooky Action: Interpretations of Quantum Physics

Questioning What Needs Interpretation

Discovering That the Most Common Interpretation Is to Shrug

Outlining Three Quantum Physics Interpretations

Enduring Debates, Bickering, and Other Counterarguments

Exploring Entangled Experiments

Part 3: By the Numbers: Basic Quantum Physics Math

Chapter 7: Entering the Matrix: Welcome to State Vectors

Creating Your Own Vectors in Hilbert Space

Making Life Easier with Dirac Notation

Grooving with Operators

Forward and Backward: Finding the Commutator

Starting from Scratch and Ending Up with Heisenberg

Eigenvectors and Eigenvalues: They’re Naturally Eigentastic!

Preparing for the Inversion: Simplifying with Unitary Operators

Comparing Matrix and Continuous Representations

Chapter 8: Getting Stuck in Energy Wells

Looking into a Square Well

Trapping Particles in Potential Wells

Trapping Particles in Infinite Square Potential Wells

Limited Potential: Taking a Look at Particles and Potential Steps

Tunneling through Forbidden Regions

Hitting the Wall: Particles and Potential Barriers

Particles Unbound: Solving the Schrödinger Equation for Free Particles

Chapter 9: Back and Forth with Harmonic Oscillators

Grappling with the Harmonic Oscillator Hamiltonians

Creation and Annihilation: Introducing the Harmonic Oscillator Operators

Mind Your p’s and q’s: Getting the Energy State Equations

Finding the Eigenstates

Chapter 10: Working with Angular Momentum on the Quantum Level

Setting Up the Hamiltonian

Ringing the Operators: Round and Round with Angular Momentum

Finding Commutators of L

x

, L

y

, and L

z

Creating the Angular Momentum Eigenstates

Finding the Angular Momentum Eigenvalues

Finding the Eigenvalues of the Raising and Lowering Operators

Interpreting Angular Momentum with Matrices

Rounding It Out: Switching to the Spherical Coordinate System

Chapter 11: Getting Dizzy with Spin

Investigating the Stern-Gerlach Experiment and the Case of the Missing Spot

Getting Down and Dirty with Spin and Eigenstates

Halves and Integers: Saying Hello to Fermions and Bosons

Spin Operators: Running Around with Angular Momentum

Working with Spin ½ and Pauli Matrices

Part 4: Going 3D with Quantum Physics Calculations

Chapter 12: Rectangular Coordinates: Solving Problems in 3D

Viewing the Schrödinger Equation in 3D!

Solving 3D Free Particle Problems

Getting Squared Away with 3D Rectangular Potentials

Springing into 3D Harmonic Oscillators

Chapter 13: Solving Spherical Coordinate Problems

Choosing Spherical Coordinates

Observing Central Potentials in 3D

Handling Free Particles in 3D with Spherical Coordinates

Handling the Spherical Square Well Potential

Getting the Goods on Isotropic Harmonic Oscillators

Chapter 14: The Simplest Atom: Understanding Hydrogen

Revisiting Atomism

Coming to Terms: The Schrödinger Equation for the Hydrogen Atom

Going General with the Hydrogen Wave Function

Calculating the Energy Degeneracy of the Hydrogen Atom

Hunting the Elusive Electron

Chapter 15: Handling Many Particles and Group Dynamics

Many-Particle Systems, Generally Speaking

Working with Identical Noninteracting Particles

Giving Systems a Push: Perturbation Theory

When Particles Collide: Scattering Theory

Part 5: The Part of Tens

Chapter 16: Ten Important Quantum Physics Pioneers

Max Planck (1858–1947)

Albert Einstein (1879–1955)

Niels Bohr (1885–1962)

Louis de Broglie (1892–1987)

Werner Heisenberg (1901–1976)

Erwin Schrödinger (1887–1961)

Paul Dirac (1902–1984)

Max Born (1882–1970)

Richard Feynman (1918–1988)

Murray Gell-Mann (1929–2019)

Chapter 17: Ten Quantum Physics Triumphs

Wave-Particle Duality

The Photoelectric Effect

Postulating Spin

Differences between Newton’s Laws and Quantum Physics

Heisenberg Uncertainty Principle

Quantum Tunneling

Discrete Spectra of Atoms

Harmonic Oscillator

Square Wells

Schrödinger’s Cat

Index

About the Author

Advertisement Page

Connect with Dummies

End User License Agreement

List of Tables

Chapter 2

TABLE 2-1 Maxwell’s Equations

Chapter 14

TABLE 14-1 Early Atom-Related Milestones

List of Illustrations

Chapter 2

FIGURE 2-1: Two vectors that have the same magnitude, but different directions.

FIGURE 2-2: An example of a wave.

FIGURE 2-3: A graph of the sine and cosine functions.

FIGURE 2-4: Waves come in two types — transverse, shown on top, and longitudina...

FIGURE 2-5: When two waves overlap, the total displacement is the sum of the tw...

FIGURE 2-6: Diffraction in action through a single slit.

FIGURE 2-7: Light moving through the two slits as a wave would create a series ...

FIGURE 2-8: The electric force and magnetic force are in step in an electromagn...

FIGURE 2-9: The Michelson-Morley interferometer sends light beams along two dif...

FIGURE 2-10: Cathode ray tubes allow charged particles to be studied in a vacuu...

Chapter 3

FIGURE 3-1: A black body.

FIGURE 3-2: Black-body radiation spectrum.

FIGURE 3-3: The photoelectric effect.

FIGURE 3-4: Kinetic energy of emitted electrons versus frequency of the inciden...

FIGURE 3-5: Light incident on an electron at rest.

FIGURE 3-6: Photon scattering off an electron.

FIGURE 3-7: An electron beam going through two slits.

FIGURE 3-8: (Left) A particle and antiparticle annihilate each other, releasing...

FIGURE 3-9: A Feynman diagram demonstrates how two particles interact with each...

Chapter 8

FIGURE 8-1: A square well.

FIGURE 8-2: A potential well.

FIGURE 8-3: Wave functions in a square well.

FIGURE 8-4: A potential step, E > V

0

.

FIGURE 8-5: The value of

k

by region, where E > V

0.

FIGURE 8-6: A potential step, E < V

0

.

FIGURE 8-7: The value of

k

by region, E < V

0.

FIGURE 8-8: A potential barrier E > V

0

.

FIGURE 8-9: |

ψ

(

x

)|

2

for a potential barrier E > V

0.

FIGURE 8-10: A potential barrier E < V

0

.

FIGURE 8-11: |

ψ

(

x

)|

2

for a potential barrier E < V

0

.

FIGURE 8-12: A Gaussian wave packet.

Chapter 9

FIGURE 9-1: The ground state of a quantum mechanical harmonic oscillator.

FIGURE 9-2: The first excited state of a quantum mechanical harmonic oscillator...

FIGURE 9-3: The second excited state of a quantum mechanical harmonic oscillato...

FIGURE 9-4: A proton undergoing harmonic oscillation.

Chapter 10

FIGURE 10-1: A rotating disk with angular momentum vector L.

FIGURE 10-2: L and L

z

.

FIGURE 10-3: A rotating diatomic molecule.

FIGURE 10-4: The spherical coordinate system.

Chapter 11

FIGURE 11-1: The Stern-Gerlach experiment.

FIGURE 11-2: Spin magnitude and

z

projection.

Chapter 12

FIGURE 12-1: A free particle in 3D.

FIGURE 12-2: A box potential in 3D.

FIGURE 12-3: A harmonic oscillator.

Chapter 13

FIGURE 13-1: The spherical coordinate system.

FIGURE 13-2: The spherical square well potential.

Chapter 14

FIGURE 14-1: The hydrogen atom.

FIGURE 14-2: The radial wave functions R

10

(

r

), R

20

(

r

), and R

21

(

r

), top to botto...

FIGURE 14-3: The electron clouds for the , , and states.

Chapter 15

FIGURE 15-1: A multi-particle system.

FIGURE 15-2: A multi-electron atom.

FIGURE 15-3: An electron colliding with another electron.

FIGURE 15-4: An electron colliding with another electron.

FIGURE 15-5: A harmonic oscillator.

FIGURE 15-6: Applying an electric field to a harmonic oscillator.

FIGURE 15-7: Scattering from a target.

FIGURE 15-8: Scattering in the lab frame.

Guide

Cover

Table of Contents

Title Page

Copyright

Begin Reading

Index

About the Author

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Quantum Physics For Dummies®, 3rd Edition

Published by: John Wiley & Sons, Inc., 111 River Street, Hoboken, NJ 07030-5774, www.wiley.com

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Media and software compilation copyright © 2024 by John Wiley & Sons, Inc. All rights reserved.

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Introduction

Physics as a general discipline has no limits; it encompasses physical phenomena from the very huge (galaxy-wide) to the very small (atoms and smaller). This book is about the very small side of things — that’s the specialty of quantum physics. When you quantize something, you can’t go smaller; you’re dealing with the tiniest discrete units of matter.

Classical physics is terrific at explaining the science behind activities such as heating cups of coffee, accelerating down ramps, or colliding vehicles (as well as a million other things), but it has problems when physical matter gets very small. Quantum physics usually deals with the micro world and examines activities such as what happens when you look at individual electrons zipping around in an atom. And when you get to that tiny level, goings-on can become very strange.

Quantum physics contains principles of uncertainty that affect physicists’ ability to precisely identify a particle’s physical characteristics. For example, you can’t know (with perfect accuracy) a particle’s exact position and its momentum at the same time. Quantum physics also explains the way that the energy levels of the electrons bound in an atom work. As physicists probed ever deeper for a way to model reality, quantum physics allowed them to figure out more about this microscopic realm of matter and energy. You encounter all of these topics, and more, in this book.

About This Book

This book contains the need-to-know concepts of quantum physics, including the history of how it was discovered, explanations (and thought experiments) outlining its core issues and debates, and the math needed to dive into some of its central problems.

Quantum physics is one of the most conceptually confusing subjects known to science. It’s a subject about which there can be heated, fundamental debates among even the most distinguished experts. The first several chapters focus on exploring the underlying science, how quantum physics ideas were discovered, and the core scientific concepts.

But ultimately, quantum physics is about solving equations, and this book doesn’t shy away from that. Starting with Chapter 7, this book assumes a fairly high level of mathematical proficiency. You can’t fully appreciate the subject without getting into calculus, and beyond that into subjects such as linear algebra and differential equations.

As you read through the book, you find that I use the following conventions:

Italics

indicate a technical term related to quantum physics, usually the first time it appears. The italicized term is closely followed by its definition or explanation. When that term crops up in later chapters, it isn’t necessarily italicized.

Numbered steps

— when working through problems in this book — serve to help organize the process of solving them.

To make the content more accessible, I divided it into five parts:

Part

1

: Getting Started with Quantum Physics:

In this part, find out about the basic principles of quantum physics, the physical concepts that led up to them, and the history of their discovery and refinement.

Part

2

: The Fundamentals — Quantum Physics Principles and Theories:

This part helps you dig more deeply into the concepts that are at the core of quantum physics, from wave-particle duality and the various types of physical particles, to the possible interpretations of quantum physics.

Part

3

: By the Numbers — Basic Quantum Physics Math:

In this part, discover the mathematics that underlies the discoveries of quantum physics, including the notations that physicists have adopted in this field. Then, using that understanding, walk through some of the more direct problems that you can solve with quantum physics.

Part

4

: Going 3D with Quantum Physics Calculations:

This part directs you to tackle more complicated problems in quantum physics, including using rectangular and spherical coordinates to approach these problems. You also begin to explore the hydrogen atom and multiple subatomic particles that interact with each other.

Part

5

: The Part of Tens:

Enjoy this part as you discover more about some of the key figures and triumphs of quantum physics.

Foolish Assumptions

I don’t assume that you have any knowledge of quantum physics when you start to read this book. However, I do make the following assumptions that you

Are taking a college-level course in quantum physics, or are interested in how math describes the motion and energy of matter on the atomic and subatomic scales.

Have some math prowess to understand the content that starts in

Chapter 7

. In particular, you know calculus and trigonometry, and how to refer to a table of differential equations. You also have some experience with linear algebra in describing a Hilbert space.

Have some classical physics background. If you’ve had a year of college-level physics (or know everything from

Physics For Dummies

), then you should have a solid base of foundational concepts.

Icons Used in This Book

Throughout this book, icons in the margins highlight certain types of valuable information that call out for your attention. Here are the icons you encounter and a brief description of each.

The Tip icon marks tips and shortcuts that you can use to make quantum physics easier.

The Remember icon marks the information that’s especially important to know. To siphon off the most important information in each chapter, just skim through these icons.

The Technical Stuff icon marks information of a highly technical nature that you can normally skip over.

The Warning icon tells you to watch out! It marks important information that may save you headaches, mostly related to common misconceptions about quantum physics.

Beyond the Book

In addition to the abundance of information and guidance related to quantum physics that I provide in this book, you get access to even more help and information online at Dummies.com. Check out this book’s online Cheat Sheet; just go to www.dummies.com and search for “Quantum Physics For Dummies Cheat Sheet.”

Where to Go from Here

This book isn’t intended as a linear read, so you can jump around in the content as needed. If you’re interested in quantum physics but don’t have a strong science background, start at the very beginning in Chapter 1 and work your way through. If you feel you have a solid grasp on classical physics, and want to focus only on the quantum stuff, then you can skip Chapter 2. If you’ve got a pretty good handle on the conceptual elements of quantum physics and really want to see how to work with the math, then grab your differential equation tables and jump straight to Chapter 7.

And if you’re interested in a specific topic that I don’t mention in the previous paragraph, you can look for it in the (front of book) Table of Contents or the (back of book) Index.

Part 1

Getting Started with Quantum Physics

IN THIS PART …

Find out about the basic concepts at the heart of quantum physics.

Examine underlying classical physics concepts.

Dive into the major experiments and discoveries of quantum physics.

Chapter 1

What Is Quantum Physics, Anyway?

IN THIS CHAPTER

Laying a physics foundation

Identifying key elements of quantum physics

Understanding the scale of quantum physics

Thinking about experiments and their results

Throughout the twentieth century, quantum physics transformed our world. Humanity went from a species that questioned whether atoms existed to one that harnessed the power of the atom. Humans also used the understanding of atoms and subatomic particles to create desktop computers out of microscopic transistors — feats made possible by quantum physics.

Homes across the globe are powered by streams of electrons, a subatomic particle that had been discovered but was barely understood before the rise of quantum physics. The first computers stored information on physical cards, but then transitioned to using magnetism, on both hard drives and floppy diskettes. For a time, humanity stored information on compact disks that machines read by using lasers (also a product of quantum physics). Now, a common storage medium is a solid-state drive (SSD) built of semiconductors (another quantum physics outcome), and most people carry micro supercomputers (called smartphones) in their pockets.

In this chapter, I provide a high-level discussion of the transformation from the classical to quantum understanding of matter and energy. I talk briefly about the world before the discovery of quantum physics and then introduce the key features that physicists discovered when they first began exploring the quantum nature of reality. I discuss why people don’t see these quantum effects in their everyday lives, and how improvements in technology allow them to first see and then expand on these understandings to grow their knowledge of physics.

The Classics: Pre-Quantum Physics

At its core, physics is the scientific study of the fundamental elements of physical reality: matter and energy. As you scale up the physical structure, and this matter and energy takes the form of chemicals mixed together or, say, a squirrel, the scientific study becomes chemistry and biology. But if you’re talking about the baseline study of matter and energy, that means you’re talking about physics.

Any scientific field, of course, has a lot of sub-disciplines. If you are studying the squirrel, for example, you aren’t just studying biology, but also zoology (the study of animals). If you’re studying how an acorn grows into a tree, then that would be biology but also botany (the study of plants).

If you’re studying the path of an acorn hurled from a tree by an angry squirrel, well, that’s physics. But it’s also the specific field of kinematics. Physics includes many sub-fields, including thermodynamics (the study of heat energy), optics (the study of light), and electromagnetism (the study of electricity and magnetism).

Throughout this book, I assume that you, the reader, have a general understanding of the basic ideas of classical physics. Chapter 2 focuses on many of the disciplines of classical physics that study matter and energy in different forms and structures. And as these studies became more detailed, they left questions that laid the foundation, at the end of the nineteenth century, for the discovery of an entirely new field of physics — quantum physics.

What Makes Physics Quantum?

Quantum physics refers to a series of discoveries from the first half of the twentieth century and the scientific explanations related to those discoveries. The insights from these explanations revolutionized the understanding of matter and energy at the smallest scale and caused a transformation in the fundamental way that physicists describe and think about the physical reality of these structures. I cover these revolutionary discoveries and experiments in detail in Chapter 3.

But what are the key insights that make quantum physics different from the physics that came before it? A couple of major differences are central to understanding how quantum physics differs from classical physics.

Quantization:

Physical quantities are measured in discrete units, packets, or

quanta

that cannot be broken down any further.

Uncertainty and probability:

Systems have inherent uncertainty built into them.

The bulk of this book explores how these two ideas interact with each other and show up in quantum physical systems, and the implications that arise from them. Note: These implications often seem counterintuitive.

The main misperception that you need to overcome in studying quantum physics is, to put it bluntly, that you actually understand how the universe operates.

In quantum physics, when your hand rests on a table, you aren’t looking at two solid physical objects. You are looking at two fields of particles interacting together in a particular way. Both are made up mostly of vast, empty space, but they somehow still push against each other. Thinking of this situation as two solid surfaces pressing against each other isn’t wrong, it just doesn’t represent the activity going on at the quantum mechanical level. The solid surfaces that you see and feel are an outcome of all of the more fundamental quantum physical interactions.

A Matter of Scale, or a Scale of Matter

Part of the reason physicists took so long to figure out these quantum elements of physical reality is that the elements become apparent only at extremely small scales. In their normal lives, people go around interacting with large, macroscopic systems.

It’s worth noting what the word large means in this context. A grain of sand is estimated to contain anywhere from 1 quintillion to 100 quintillion atoms. That estimate translates to more than 100,000,000,000,000,000,000 (1020) atoms in a single grain of sand — or about as many atoms in a grain of sand as there are stars in the universe. And a grain of sand is so large that you don’t need to take quantum physics into account to figure out how it behaves.

These large systems (relatively speaking) have the quantum effects washed out. So, although each individual atom involves quantum uncertainty, when you look at the full 100 quintillion atoms in the grain of sand, all of those quantum uncertainties cancel each other out. When viewed as a whole, the quantum uncertainty that remains on the grain of sand is completely irrelevant.

Physicists began to notice quantum physics only after they could look at a single atom or, even more precisely, after they began to look inside of a single atom — for example, when they examined electrons within an atom or the structure of the atomic nucleus. This tiny level was where quantum behaviors really became evident.

Quantum physics discoveries enabled physicists to finally begin to understand what was going on inside of atoms. The modern understanding of atomic structures is entirely built upon the understanding of quantum physics, even though the macroscopic physical structures that come out of those atoms — whether a grain of sand, a squirrel, or a planet — don’t exhibit the same quantum behaviors that you can see when looking at their smallest pieces.

Measurements and Observables: How Scientists Know Quantum Physics Is True

Quantum mechanics is a means of carefully analyzing a quantum physical situation and describing the observable outcomes of measuring a quantum mechanical experiment. Although some key insights guide the field, quantum mechanics is driven largely by the fact that the equations that are used work. The equations are complex and messy; they required years of mathematical and physical study to fully understand them. But when you do figure out how these equations work, they give you information that matches with the observable output of an experiment.

Because quantum physics relies on behavior that people don’t experience in their day-to-day world, one of the biggest challenges for those studying quantum physics is learning how to rely on abstract understandings that are inconsistent with their natural intuitions.

Studying classical physics is a cakewalk by comparison because people have natural intuitions that are completely consistent with classical physics. Many a child can toss a ball at the right angle to be caught by another child. (Not me, necessarily, but many other children could do it.)

Doing the right tests

Researchers know that, to show whether anything in science is true, the explanation must match with experimental outcomes. In many cases, the findings of experimental results are fairly consistent with your intuitions, but in some cases, accepting the findings involves realizing when your intuitions are wrong.

Almost everything learned in quantum physics experimentation involves people realizing that their intuitions are wrong.

To use a historical example, thinkers going back to before the ancient Greeks believed that heavier objects fell at faster rates than lighter objects. This is a very intuitive thing to believe and is probably still the guess most children would make about how things fall.

Not only is this idea intuitive, but it is even supported by simple experiments. If you have two balls of exactly the same size, but one is made of lead and one is made of foam, the lead ball (when dropped in a simple experiment) is going to hit the ground first. But if you create a more careful experiment, which eliminates the possible impact of wind (or air) resistance, then you discover the same thing that scientists (or natural philosophers) discovered centuries ago: Both the balls will fall at precisely the same rate. Any experimental difference in their falling rate is actually independent of their weight. (You can find out a bit more about the laws of motion that come out of this in Chapter 2.)

It wasn’t enough to just do an experiment; scientists had to figure out how to do the right experiment. In some cases throughout history, you see that the right experiments come along with the invention of technology, such as the microscope or the telescope, which allow for tests and experiments that couldn’t be done before with the naked eye.

Similarly, the technology of the industrial revolution meant that the dawn of the twentieth century brought with it the technology needed to conduct the right kinds of experiments — many of them covered in Chapter 3 — that led scientists to uncover the quantum physical nature of reality.

Trusting (but verifying) the right tests

When the results of an experiment conflict with scientists’ intuitions, they realize that their intuitions are wrong — but maybe not instantly. Science has no shortage of scientists jumping to a belief that later proved to be wrong.

As the famed theoretical physicist Richard P. Feynman (whom I discuss in Chapters 3, 5, and 16) once said:

The first principle is that you must not fool yourself and you are the easiest person to fool.

Healthy skepticism is fundamental to science. Ideally, scientists carefully confirm their own results multiple times before sharing them. But, if the scientist has jumped ahead and perhaps violated Feynman’s first principle, then the skepticism of the scientific community should be at the ready. Any scientist wants to be up to the task of proving a popular scientific claim wrong. Doing so is a little easier than coming up with a whole new claim (and almost as much fun).

As you find out about the history of quantum physics, notably throughout Chapters 3 and 6, you see conflicts between scientists about the proper understanding of the results of physics experiments. And, even when physicists agree on the basic concepts of how to solve quantum physics problems, they have even deeper disagreements on how to interpret those solutions!

For over the last century, though, the results of quantum physics have been put to the test over and over again, and the results have constantly proven to be consistent with the mathematical solutions of the theory. Even while there is strong disagreement about the interpretation and meaning of those solutions, physicists set aside those disagreements and go on to work on applying quantum physics to build particle accelerators, create exotic superfluid states of matter, build semiconductors and transistors, and continually expand the limits of what people can create.