The future superconducting linear accelerator of Spiral2 will provide very high intensity of stable ions beams. They can be used to produce nuclei with very low cross sections, like superheavy elements or neutron deficient nuclei close to the limit of stability. S3 has been designed to handle these intense beams and select the rare nuclei of interest among the majority of contaminants, to identify and study them. The Irfu is in charge of the primary selection line and strongly involved in the design of the detection set-up.
From 2015, the LINAG accelerator in GANIL will be able to produce stable heavy ion beams of unprecedented currents. They will be a factor 10 to 100 more intense than present beams. These stable ion beams will enable to deepen our knowledge in many aspects of physics by various experiments:
To use these high intensities above 1014 particles per second, which is beyond the limit of any detector, it is necessary to develop a new kind of device. It should separate the interesting nuclei which are only a tiny part of the transmitted ions after the target – most of them are beam ions that did not interact with the target. The aim is to obtain after separation counting rates of the order of 1kHz or less, compatible with a normal detection. The S3 spectrometer is designed to achieve this goal. S3 is a device that includes:
Superconducting high aperture magnets, combining quadrupole, sextupole and octupole fields, permit a high transmission and a high mass resolution.
Irfu has taken in charge the “primary selection line” of S3, which in located at the first momentum dispersive plane. Its function is to ensure the rejection of the majority of the primary beam that passed trough the target without nuclear interaction. These ions, with different charge state can be blocked in different parts of the Primary rejection line. Each beam dump must be able to sustain the very high power of the incoming beam (up to a total of 40kW). When the beam is within the momentum acceptance of the spectrometer, specific, thin beam dumps (“fingers”) are designed to block the very high power density of the beam (up to 5kW/cm2) while letting most of the nuclei of interest pass through. When the beam is outside of the acceptance, the quadrupole magnets with embedded sextupole corrections have a horizontal aperture to bring the beam in a lateral dump. Due to the very high intensities, the resulting radio-activation of the material is also very important. All beam dumps can be fully enclosed in a lead shielding, ensuring a minimal radioactivity to the environment and the staff.
The Irfu is also involved in the development of a high resolution decay spectroscopy station. Located at the end of S3, this set-up will perform alpha, proton, electron and gamma spectroscopy of the nuclei that have been transmitted through S3. This device is specially designed to study the decays of superheavy elements that are produced by fusion-evaporation reactions, in order to study already known elements of identify new ones. This detection system uses low dead zone, large size silicon detector optimized for the detection of heavy ions. Its innovative electronics combine high resolution with high dynamics and a very low dead time, to be able to detect the fast decay chains following the heavy ion implantation.
S3 is under construction and its commissioning will start in 2015.
Visit the S3 webpage at GANIL.
Last update : 06/26 2017 (943)
Study of the formation of superheavy nuclei
The heavier element ever found on Earth is Uranium-238 (half-life of the order of 5 109 years). For 60 years, till 2005, nearly 20 elements heavier than U were synthesized in laboratory, with shorter life periods. In 2003, the last element, whose existence was confirmed, was the Z=112 isotope, produced at GSI (Darmstadt).