Fields in Physics

Quantum field theory is the most advanced scientific theory ever developed by humans. It is based on the quantum framework, but the main object of the theory are fields. Fields in physics are the most adequate entity physicists have found to describe reality. Two famous examples are the magnetic field and the electric field, thanks to which almost every device from mobile phones to particle accelerators works.

What are fields, and why are they important?

We are going to analyse how the concept of field evolved historically and what motivated its surge and evolution. Then, we will review some of the important consequences field theories have in physics.

Historical notions of field

Already in ancient Greece, philosophers and mathematicians developed an intuition regarding, mostly, non-contact forces of something that existed in space and caused things to move or behave in certain ways. A precise mathematical formulation of this idea was not achieved until Newton formulated his theory of gravitation. Since then, the basic characteristics of fields came understood to be:

• Presence of a source responsible for the existence of the field. For instance, the usual source of the magnetic field is a magnet. In modern physics, advanced theories and measurements have led to the discovery of certain particles ‘carrying’ the interaction, such as photons in the case of the electromagnetic field.
• Spacelike character: the field might behave as a scalar quantity throughout space, showing only magnitude, or it might have a direction or other more complicated features. For example, gravity has a direction towards the earth but temperature matters only as a number measuring its intensity.
• Locality: this is the key characteristic of usual fields, which are functions of spacetime. That means that the most general field takes different values for different locations of space, and it evolves in time for each point. For instance, the temperature in a room changes over time and will be higher the closer we get to the heater.

Figure 1. Example of a direction field.

Although the spacelike character was quickly understood by scientists and philosophers, the nature of sources and of locality were widely questioned throughout history. Regarding the sources, it is true that, according to our understanding of fields, a proper source does not always exist, as, for instance, for temperature.

On the other hand, the issue of locality has posed a greater challenge when modelling and understanding fields. For example, it used to be believed that temperature was generated in ‘bubbles’ that floated around. Nowadays, although locality is a widely accepted principle, some non-local effects have led us to believe that it is approximately but not fully correct.

The importance of fields

Most physics problems in high school involve highly simplified forces acting in a very local way but only at a certain point in space. We find point-like particles to be the elemental objects that we work with. We have examples of these in the charges responsible for creating an electric field or in the majority of modern atomic models when considering the electron. Fields are a generalisation for the whole space of the local point-like forces we have mentioned. In the end, this is all thanks to the fact that interactions caused by fields occur in points smaller than any scale we consider.