The Solid-State Neutron Detector – SoNDe – project aimed to develop a high-resolution neutron detector technique that will enable the construction of position-sensitive neutron detectors for high-flux sources, such as the upcoming European Spallation Source (ESS). This includes also the construction of a full-scale prototype as a research and innovation action. Moreover, by avoiding the use of 3He in this detector the 3He-shortage, which might otherwise impede the construction of such large-scale facilities, can be alleviated. The main features of the SoNDe type detector are:
• high-flux capability (up to 100 MHz on a 1x1 m2 detector)
• high-resolution of 3 mm by single-pixel technique, below by interpolation
• neutron detection efficiency >= 90 %
• no beam stop necessary, thus enabling investigations with direct beam intensity
• strategic independence of 3He using scintillator technology
• time-of-flight (TOF) capability, necessary to exploit maximum flux, time resolution better than 100 ns
• modularity, improving maintenance characteristics of today’s neutron detectors
Compared to previous neutron detectors this is a huge step forward in terms of count-rate and efficiency. Such gain factors will be needed to make the best possible use of sources such as the European Spallation Source (Sweden), the Institut Laue-Langevin (France) and the Maier-Leibnitz Zentrum (Germany), which are detailed in the European Strategy Forum on Research Infrastructures (ESFRI) roadmap. Benefiting instruments at such a facility, among others, would be Small-Angle Neutron Scattering (SANS) instruments such as SKADI at the upcoming ESS, which was recently approved by the scientific advisory committee, neutron reflectometers and any instrument needing to detect neutrons with a millimetre accuracy on a large detector area.
Detectors of this kind will be capable of usage in a wide array of neutron instruments at facilities of European interest, which use neutrons to conduct their research, among them the Institute Laue-Langevin (ILL) in France, the Maier-Leibnitz-Zentrum (MLZ, former FRMII) in Germany, Laboratoire Léon-Brillouin (LLB) in France and ISIS in the United Kingdom which are in operation at the moment and the upcoming ESS. At these facilities neutrons are used as a probe in a wide array of fields, ranging from material science to develop new and smart materials, chemical and biological science to develop new drugs for improved treatment of a wide range of medical conditions, magnetic studies for the development of future information storage technology to archaeology, probing historical artefacts on a molecular level without physically destroying them.
In addition to the application of the SoNDe technology its modularity also allows applications in material testing, border control or teaching and research on a laboratory scale. Those additional applications create an even wider impact than the originally projected use in large scale facilties. It also illustrates the benefit of technical developments in research environments as the trickle down to other applications in most cases potentiates the cost-benefit ratio.