Pandemonium effect
The pandemonium effect is a problem that may appear when high-resolution detectors are used in beta decay studies. It can affect the correct determination of the feeding to the different levels of the daughter nucleus. It was first introduced in 1977.
Context
Typically, when a parent nucleus beta-decays into its daughter, there is some final energy available which is shared between the final products of the decay. This is called the Q value of the beta decay. The daughter nucleus doesn't necessarily end up in the ground state after the decay, this only happens when the other products have taken all the available energy with them. So, in general, the daughter nucleus keeps an amount of the available energy as excitation energy and ends up in an excited state associated to some energy level, as seen in the picture. The daughter nucleus can only stay in that excited state for a small amount of time after which it suffers a series of gamma transitions to its lower energy levels. These transitions allow the daughter nucleus to emit the excitation energy as one or more gamma rays until it reaches its ground state, thus getting rid of all the excitation energy that it kept from the decay.According to this, the energy levels of the daughter nucleus can be populated in two ways:
- by direct beta feeding from the beta decay of the parent into the daughter,
- by gamma transitions of higher energy levels into lower energy levels.
The beta feeding Iβ can not be measured directly. Since the only magnitude that can be measured are the gamma intensities ΣIi and IT, the beta feeding has to be extracted indirectly by subtracting the contribution from gamma de-excitations of higher energy levels to the total gamma intensity that leaves the level, that is:
Description
The pandemonium effect appears when the daughter nucleus has a large Q value, allowing the access to many nuclear configurations, which translates in many excitation-energy levels available. This means that the total beta feeding will be fragmented, because it will spread over all the available levels. Then, the gamma intensity emitted from the less populated levels will be weak, and it will be weaker as we go to higher energies where the level density can be huge. Also, the energy of the gammas de-excitating this high-density-level region can be high.Measuring these gamma rays with high-resolution detectors may present two problems:
- First, these detectors have a very low efficiency of the order of 1–5%, and will be blind to a weak gamma radiation in most of the cases.
- Second, their efficiency curve drops to very low values as it goes to higher energies, starting from energies of the order of 1–2 MeV. This means that most of the information coming from gamma rays of huge energies will be lost.
When this happens, the low-lying energy levels are the more affected ones. Some of the level schemes of nuclei that appear in the nuclear databases suffer from this Pandemonium effect and are not reliable until better measurements are made in the future.