germanium and Emergencies

During emergencies following a major nuclear accident a prompt and accurate characterisation of the radioactive cloud is one of the main task of any radioactivity monitoring system. This task is usually performed by means of γ-spectrometry High Purity Germanium (HPGe) measurements on atmospheric particulate samples gathered by means of high-volume pumps. The key parameters describing the performances of a monitoring system are the Minimum Detectable Activities (MDAs) of the most relevant radionuclides. These parameters depend on a number of factors related to the efficiency of the available germanium detector, the volume of air filtered by the sampling devices and the γ-decay scheme of each radionuclides as well. Besides the MDAs, another very important characteristic of a monitoring system, especially during an evolving emergency, is its capability of giving reliable results at a given and constant pace. It is therefore important to define the time resolution of the monitoring system, i.e. the minimum time needed to produce the data, namely the activity concentrations of the radionuclides in the atmosphere. The optimization of the measurements procedures are discussed in this work: in particular it is demonstrated that, being t the time resolution of the monitoring system, the lowest MDAs can be achieved with a sampling time given by (2/3)·t and a counting time of (1/3)·t. Finally, the MDAs achievable for a standard monitoring system based on a 30% HPGe detector are calculated for all the most important fission products.

Topics: Atmosphere; Dust; Emergencies; Germanium; Humans; Spectrometry, Gamma

Currently, the territorial Radiation Monitoring Network (RMN) of the Czech Republic consists of seven laboratories equipped with gamma spectrometry High Purity Germanium (HPGe) detectors. From 2007 to 2018, five emergency exercises were carried out to test the sample throughput of these facilities and their staff. The main objective was to identify weaknesses and problem areas in the whole process from the moment of obtaining the samples to logging the results into the central RMN database. The long-term aim of these exercises is to optimize emergency response procedures. The most important factor limiting laboratory capacity is the lack of qualified personnel. The exercises showed that in the current state, these laboratories would be able to operate in 12-hour shifts for 14 days and analyze 1700 samples per day. Emergency exercises have highlighted the fact that this type of exercise should be repeated periodically in order to monitor the performance and analytical capabilities of RMN.

Topics: Civil Defense; Czech Republic; Disaster Planning; Emergencies; Germanium; Humans; Laboratories; Radiation Monitoring; Spectrometry, Gamma