Basic Physics Of Quantum Theory, The. Basil S Davis

      Microscopic particles have no color and even the idea of shape has little meaning in this realm. And because they have no trajectories, it becomes impossible to picture them in our minds. And so quantum theory is necessarily abstract. This abstraction arises from the very nature of the behavior of microscopic objects. And in the realm of physics the language of abstraction has a mathematical shape. The mathematical methods used in quantum theory constitute what is known as quantum mechanics. In this introductory book we will not study quantum mechanics in detail, though we shall touch upon some of the basic principles of quantum mechanics. The bibliography at the end of this book lists some excellent books for the reader who wishes to move on to a rigorous study of the subject.

      Quantum physics has important applications such as the photoelectric cell, positron electron tomography, the electron microscope, superconducting magnets, etc. But in this book we shall focus on the theory, with at most a cursory mention of important applications.

      Quantum theory can be described as a study of particles and fields.¹ Particles and fields were both studied by classical physics. In classical physics these two entities were studied distinctly. So we had one sort of physics that described particles, and another sort of physics that described fields. Newton’s Laws of motion describe particle motion, and Maxwell’s equations describe the electromagnetic field. But in quantum theory both these entities come together. A particle is a particle of a field, and a field is a field of a particle. This statement may sound meaningless, but it expresses a very basic concept of quantum theory. But before we attempt to unpack this concept, we shall perform a review of classical physics (Chs. 2, 3 and 4) to get a better understanding of particles and fields in their own right.

      The word particle means a solid object that is sufficiently small so that its dimensions can be neglected, and our interest is only in the motion of the particle. A particle could be physically as small as an electron, but if we are considering the dynamics of the solar system as a whole, an entire planet can be considered as a particle, since the size of the planet is small compared to the radius of its orbit round the sun. Particles feature prominently in the mechanics based on Newton’s laws of motion.

      The word field signifies a region of space that has an effect on certain particles that are present in that region. An apple that hangs from a tree experiences a force caused by the earth’s gravitational field. A charged particle such as an electron is affected by electric and magnetic fields. A positively charged proton creates an electric field that extends in all directions leading away from the proton. This field gets progressively weaker as one moves further away. If another charged particle — say an electron — were to be brought near the proton, it would experience a force of attraction towards the proton. So in this case the proton is like the earth which produces the field, and the electron is like the apple which experiences a force due to the field. (For the sake of accuracy we clarify that both the earth and the apple generate their own gravitational fields, and both the proton and the electron generate their own electric fields.)

1.3 Outline of the book

      We will first do a quick review of the classical physics of particles which will give us a lead into the notion of particles in quantum theory. Chapter 2 will cover the fundamental classical mechanics of particle motion. It is impossible to understand modern physics without a basic knowledge of classical Newtonian physics. Chapter 3 will examine the significance of the atomic structure of matter. This chapter is entitled Statistical Mechanics to draw attention to this very important area of physics. Statistical mechanics played a historical role in the advent of quantum theory, as will be explained in Ch. 5, and today figures prominently in the rapidly growing branch of physics called quantum information theory. Chapter 4 will outline the classical physics of fields — specifically gravitational and electromagnetic — which will set up the background for understanding the notion of a field in quantum theory. The subsequent chapters will explain quantum theory in detail, beginning with its historical origin in Ch. 5. An important concept in modern quantum theory is entanglement, which cannot be appreciated without a knowledge of Relativity, and so Chs. 8 and 9 are devoted to explaining the concepts and the implications of Einstein’s Special Theory of Relativity. We keep the mathematics to a bare minimum throughout, because this book is meant to serve as an introduction that is accessible to readers who may not have a strong mathematical background.

      Quantum mechanics is a thoroughly mathematical discipline, requiring algebra and calculus. But because our aim is to avoid mathematics as far as that is possible, we will not do much quantum mechanics in this book. Nevertheless, the foundational principles of quantum mechanics can be learnt without a great deal of mathematics, and so we will present these principles in the course of this book.

      Numerical calculations are helpful for gaining a better understanding of physics, and so we have provided simple numerical exercises throughout the book. A knowledge of basic algebra is sufficient to work out these exercises. Answers to the exercises (where required) are provided in an appendix at the end of the book.