The RADNEXT Consortium is composed of 35 partners.
20 of them will shortly present their activities/ contributions to the RADNEXT project.
In the work package WP6-JRA2, the main goal will be the exploration of valid qualification procedures to be effective at system level. For this purpose, we define with the term system as a structure composed of basic electronic elements such as transistors, diodes, capacitors and complex elements such as ADC/DAC converters, frequency synthesizers, voltage regulators, memories, processors,...
In this Work Package (WP7-JRA3) a study of the cumulative radiation effects on electronics will be accomplished. Cumulative effects in electronics are highly relevant both for actual applications (e.g. space, high-energy accelerators, nuclear dismantling, etc.) as well as related to by-product effects of Single Event Effects (SEE) testing.
Two main tasks will be studied. The first one is...
This WP will develop and apply tools and approaches for modelling radiation effects on electronics. These require a multi-physics approach, at radiation-matter interaction, semiconductor physics and circuit level. The modelling efforts will be focused on:
Benchmarking simulation tools to be used for SEE applications as complement to experimental data, in order to enhance the understanding...
In this Work Package (WP5-JRA1), the RADNEXT facilities and user needs will be defined and answered in terms of radiation detectors, beam instrumentation and dosimetry. This Work Package includes three main tasks:
- To define the correlation matrix between the identified needs and the established or innovative monitoring solutions as well as the definition and standardization of the...
The RADNEXT Consortium is composed of 35 partners.
15 of them will shortly present their activities/ contributions to the RADNEXT project.
The work package will provide transnational access to 14 facilities for the irradiation of electronics with neutron, muon and mixed-fields. The offer of neutron beams is the core of the WP, and covers a wide range of energy and fluxes, including atmospheric neutrons, thermal neutrons, monoenergetic and quasi-monoenergetic, low and intermediate energy white beams. Two facilities, providing...
This WP provides Transnational Access for scientific users to a diverse network of proton and heavy-ion facilities providing energetic beams for SEE testing. The beam energies provided are ranging from low energy protons of below MeV energies up to ultra high heavy ions at several GeV/u. There are also facilities capable of producing highly focused micro ion beams that will be useful in...
The overall objective of the communication, dissemination, exploitation and training activities within RADNEXT is to increase and maximize the project impact (economic, commercial, societal, environmental, technical, educational, and scientific).
A variety of media will be used for attracting new users (e.g. SMEs), demonstrating relevance of accelerator infrastructures for society, creating...
Efficiently awarding beam time to radiation effects users worldwide will be the cornerstone of the RADNEXT project, therefore a clear and effective approach to the Transnational Access is a key requisite for success.
To this aim, WP2 is fully devoted to the management of the Transnational Access (TA) activities: application for beam time, coordination of the user selection and support,...
The objective of this WP is to define roadmaps and provide recommendations for upgrades of current facilities and design of future ones. The WP4 goal is to underline long-term scientific, technological and industrial needs in order to prepare irradiation facilities and improve the usability of them. This task is addressed by analyzing the present and future industrial and scientific...
