It is clear that technology is changing the world in many ways, but both its impact and progress is difficult to summarise into a single equation, chart or graph. However, it is readily apparent that the advent of the transistor has played a large part in recent technological advances. Gordon Moore (1965) ably illustrated progress in this field by plotting the number of transistors on a chip as a function of time, showing that this number was doubling every two or so years, a relation now called Moore’s law. Over time, the quoted number of components on a chip has changed, but the overall trend has stayed relatively consistent for more than six decades, although it appears to have slowed a little over the last decade or so to a doubling every two and a half years. However, Moore’s plot does not contain the effect of increasing clock speeds, and newer roadmaps of this technology now incorporate this to reflect the rate at which information can be transferred and processed, typically plotting a measure of the number of calculations per second over time (see also Chapter 2, Section 2.2). Notwithstanding these details, a simplified and modified Moore’s law plot is shown in Figure 1.1. As usual, time is shown as the horizontal axis, while there are two lines showing the number of components on a chip as the primary vertical axis and component size (assuming that the chip is square and 20 mm on a side). Typically, for a chip consisting of an array of transistors, the features on this component will be around one quarter of the size. A glance at this plot shows the number of components increasing exponentially, with the size of components correspondingly reducing. For example, with a component size of 100 nm, the individual feature dimensions will be of the order 25 nm. A reduction in component size to 10 nm in the mid-2020s indicates features to have dimensions of the order of only a few nanometres. Interestingly, when the dimensions of electrical circuits approach atomic scales, quantum effects will significantly influence the nature of conduction and place constraints on the motion of electrons. Fundamentally, a wire must comprise a conductor surrounded by an insulating barrier. However, on a quantum level, the barrier only affects the probability of the electron being located in the re...