Microgan electron cyclotron resonance ion source in a Van de Graaff accelerator terminal.

The Van de Graaff accelerator at IRMM works since many years providing proton, deuteron, and helium beams for nuclear data measurements. The original ion source was of RF type with quartz bottle. This kind of source, as well known, needs regular maintenance for which the accelerator tank must be completely opened. The heavy usage at high currents of the IRMM accelerator necessitated an opening about once every month. In 2010, the full permanent magnet Microgan electron cyclotron resonance (ECR) ion source from PANTECHNIK was installed into a new terminal platform together with a solid state amplifier of 50 W, a dedicated dosing system for 4 gases (with respective gas bottles H(2), D(2), He, and Ar), and a set of dedicated power supplies and electronic devices for the remote tuning of the source. The new system shows a very stable behaviour of the produced beam allowing running the Van de Graaf without maintenance for several months. This contribution will describe the full installed system in details (working at high pressure in the terminal, spark effects, and optic of the extraction), as well as beam results in dc or pulsed mode.

Neutron field measurements for alara purposes around a Van de Graaff accelerator building.

The Institute for Reference Materials and Measurements operates a 7.0 MV Van de Graaff accelerator to generate monoenergetic neutron radiation for experimental applications. Owing to increased intensities of generated neutron fields and the more stringent regulation related to the maximum dose for the public, a concrete shielding wall surrounding the experimental building was constructed. This paper presents a study aiming at evaluating the effect of the shielding on the neutron field outside the wall. For this purpose, the following measurements were carried out around the building: (1) cartography of the neutron field for different experimental conditions; (2) measurement of neutron spectra using multiple Bonner spheres; (3) activation measurements using gold discs followed by low-level gamma spectrometry. From the measurements, it can be concluded that the wall fulfils its purpose to reduce the neutron dose rate to the surrounding area to an acceptable level.

Accumulation of calcium in substantia nigra lesions induced by status epilepticus. A microprobe analysis.

Status epilepticus of sufficient duration (greater than 30 min) causes a unique lesion of substantia nigra pars reticulata (SNPR), and of globus pallidus (GP). This lesion, which encompasses a pan-necrotic destruction of neurons and glial cells seems to develop during ongoing seizures. We decided to investigate if the lesion is accompanied by net calcium accumulation. Seizures of 20 and 60 min duration were induced by the administration of flurothyl, and the tissue was frozen in situ either at the end of the seizure periods, or after recovery periods of 15 or 120 min. The total calcium and potassium contents of caudoputamen, neocortex, GP and SNPR were measured using particle induced X-ray emission (PIXE) in the microprobe mode. Seizures of 20 min duration did not cause net accumulation of calcium. When the duration of seizures was extended to 60 min the results varied depending on the location. In caudoputamen, which does not incur neuronal damage, no calcium accumulation was observed. In GP and SNPR, such a rise was unequivocally demonstrated, with calcium content increasing to about 150% of controls. The increase in calcium correlated to a decrease in potassium content. It is concluded that epileptic cell death occurs pari passu with accumulation of calcium although it cannot be stated that this accumulation is the cause of the cell death. It is speculated that seizures increase the permeability of the blood-brain barrier to calcium, and that enhanced blood to tissue transfer increases the calcium load of metabolically strained cells.