Editing Magnetometer (section)

====Caesium vapour magnetometer====
The ''optically pumped [[caesium]] vapour magnetometer'' is a highly sensitive (300&nbsp;fT/Hz<sup>0.5</sup>) and accurate device used in a wide range of applications. It is one of a number of alkali vapours (including [[rubidium]] and [[potassium]]) that are used in this way.<ref name="snare" />

The device broadly consists of a [[photon]] emitter, such as a laser, an absorption chamber containing caesium vapour mixed with a "[[buffer gas]]" through which the emitted [[photon]]s pass, and a photon detector, arranged in that order. The buffer gas is usually [[helium]] or [[nitrogen]] and they are used to reduce collisions between the caesium vapour atoms.

The basic principle that allows the device to operate is the fact that a caesium atom can exist in any of nine [[energy level]]s, which can be informally thought of as the placement of [[electron]] [[atomic orbital]]s around the [[atomic nucleus]]. When a caesium atom within the chamber encounters a photon from the laser, it is excited to a higher energy state, emits a photon and falls to an indeterminate lower energy state. The caesium atom is "sensitive" to the photons from the laser in three of its nine energy states, and therefore, assuming a closed system, all the atoms eventually fall into a state in which all the photons from the laser pass through unhindered and are measured by the photon detector. The caesium vapour has become transparent. This process happens continuously to maintain as many of the electrons as possible in that state.

At this point, the sample (or population) is said to have been optically pumped and ready for measurement to take place. When an external field is applied it disrupts this state and causes atoms to move to different states which makes the vapour less transparent. The photo detector can measure this change and therefore measure the magnitude of the magnetic field.

In the most common type of caesium magnetometer, a very small AC magnetic field is applied to the cell. Since the difference in the energy levels of the electrons is determined by the external magnetic field, there is a frequency at which this small AC field makes the electrons change states. In this new state, the electrons once again can absorb a photon of light. This causes a signal on a photo detector that measures the light passing through the cell. The associated electronics use this fact to create a signal exactly at the frequency that corresponds to the external field.

Another type of caesium magnetometer modulates the light applied to the cell. This is referred to as a Bell-Bloom magnetometer, after the two scientists who first investigated the effect. If the light is turned on and off at the frequency corresponding to the Earth's field,{{clarify|date=July 2013}} there is a change in the signal seen at the photo detector. Again, the associated electronics use this to create a signal exactly at the frequency that corresponds to the external field. Both methods lead to high performance magnetometers.