Book contents
- Frontmatter
- Dedication
- Contents
- PREFACE
- NOTATION
- 1 HISTORICAL INTRODUCTION
- 2 PARTICLE STATES IN A CENTRAL POTENTIAL
- 3 GENERAL PRINCIPLES OF QUANTUM MECHANICS
- 4 SPIN ET CETERA
- 5 APPROXIMATIONS FOR ENERGY EIGENVALUES
- 6 APPROXIMATIONS FOR TIME-DEPENDENT PROBLEMS
- 7 POTENTIAL SCATTERING
- 8 GENERAL SCATTERING THEORY
- 9 THE CANONICAL FORMALISM
- 10 CHARGED PARTICLES IN ELECTROMAGNETIC FIELDS
- 11 THE QUANTUM THEORY OF RADIATION
- 12 ENTANGLEMENT
- AUTHOR INDEX
- SUBJECT INDEX
3 - GENERAL PRINCIPLES OF QUANTUM MECHANICS
Published online by Cambridge University Press: 05 November 2015
- Frontmatter
- Dedication
- Contents
- PREFACE
- NOTATION
- 1 HISTORICAL INTRODUCTION
- 2 PARTICLE STATES IN A CENTRAL POTENTIAL
- 3 GENERAL PRINCIPLES OF QUANTUM MECHANICS
- 4 SPIN ET CETERA
- 5 APPROXIMATIONS FOR ENERGY EIGENVALUES
- 6 APPROXIMATIONS FOR TIME-DEPENDENT PROBLEMS
- 7 POTENTIAL SCATTERING
- 8 GENERAL SCATTERING THEORY
- 9 THE CANONICAL FORMALISM
- 10 CHARGED PARTICLES IN ELECTROMAGNETIC FIELDS
- 11 THE QUANTUM THEORY OF RADIATION
- 12 ENTANGLEMENT
- AUTHOR INDEX
- SUBJECT INDEX
Summary
We have seen in the previous chapter how useful wave mechanics can be in solving physical problems. But wave mechanics has several limitations. It describes physical states by means of wave functions, which are functions of the positions of the particles of the system, but why should we single out position as the fundamental physical observable? For instance, we might want to describe states in terms of probability amplitudes for particles to have certain values of the momentum or energy rather than the position. A more fundamental limitation is that there are attributes of physical systems that cannot be described at all in terms of the positions and momenta of a set of particles. One of these attributes is spin, which will be a chief subject of Chapter 4. Another is the value of the electric or magnetic field at some point in space, treated in Chapter 11. This chapter will describe the principles of quantum mechanics in a formalism which is essentially the “transformation theory” of Dirac, mentioned briefly in Section 1.4. This formalism generalizes both the wave mechanics of Schrödinger and the matrix mechanics of Heisenberg, and is sufficiently comprehensive to apply to any sort of physical system.
States
The first postulate of quantum mechanics is that physical states can be represented as vectors in a sort of abstract space known as Hilbert space.
Before getting into Hilbert space, I need to say a bit about vectors in general. In kindergarten we learn that vectors are quantities with both magnitude and direction. Later, when we study analytic geometry, we learn instead to describe a vector in d dimensions as a string of d numbers, the components of the vector. The latter approach lends itself well to calculation, but in some respects the kindergarten version is better, because it allows us to describe relations among vectors without specifying a coordinate system. For instance, a statement that one vector is parallel to a second vector, or perpendicular to a third, has nothing to do with how we choose our coordinate system.
Here we will formulate what we mean by vector spaces in general, and Hilbert space in particular, in a way that is independent of the coordinates we use to describe directions in these spaces.
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- Lectures on Quantum Mechanics , pp. 55 - 103Publisher: Cambridge University PressPrint publication year: 2015
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