Ionization: Applications: (2) Ionising Radiation Detectors: Plot of variation of ionisation current against applied voltage for a co-axial wire cylinder gaseous radiation detector. Townsend avalanche discharges are fundamental to the operation of gaseous ionization detectors such as the Geiger-Müller tube and theProportional counter in either detecting ionizing radiation or measuring its energy. The incident radiation will ionise atoms or molecules in the gaseous medium to produce ion pairs, but different use is made by each detector type of the resultant avalanche effects. In the case of a GM tube the high electric field strength is sufficient to cause complete ionisation of the fill gas surrounding the anode from the initial creation of just one ion pair. The GM tube output carries information that the event has occurred, but no information about the energy of the incident radiation. In the case of proportional counters, multiple creation of ion pairs occurs in the "ion drift" region near the cathode. The electric field and chamber geometries are selected so that an "avalanche region" is created in the immediate proximity of the anode. A negative ion drifting towards the anode enters this region and creates a localised avalanche that is independent of those from other ion pairs, but which can still provide a multiplication effect. In this way spectroscopic information on the energy of the incident radiation is available by the magnitude of the output pulse from each initiating event. The accompanying plot shows the variation of ionisation current for a co-axial cylinder system. In the ion chamber region, there are no avalanches and the applied voltage only serves to move the ions towards the electrodes to prevent re-combination. In the proportional region, localised avalanches occur in the gas space immediately round the anode. Increasing the voltage increases the number of avalanches and thereby current, until the Geiger region is reached where the full volume of the fill gas around the anodes ionised, and all energy information is lost. Beyond the Geiger region the gas is in continuous discharge owing to the high electric field strength