To fully exploit the potential of low energy antiproton research infrastructures, the AVA partners carried out a closely connected R&D program across three scientific work packages:
Facility Design and Optimization,
addressing beam life time and stability in low energy storage rings, beam cooling, deceleration and extraction through simulation and experiment, as well as innovative control systems. Significant progress was made in the enhancements to existing simulation codes, as well as experimental studies into beam motion and cooling at the ELENA and LEIR rings at CERN. These studies were carried out in close collaboration between several AVA Fellows and have helped model the anticipated performance of the accelerator and its electron cooler better.
Beam Diagnostics,
to monitor the properties of a low energy antiproton beam with higher precision and help verify simulation models experimentally. R&D was carried out into beam profile, position and intensity measurement and prototype detectors were successfully developed and tested at the partner organizations in this work package. These have already shown superior performance as compared to existing technologies and are expected to mark the state-of-the-art in the future.
Antimatter Experiments,
including experiments into the effects of gravity on antimatter and spectroscopic measurements that give an insight into the structure of antiparticles. R&D has addressed a wide range of experimental studies and led to the development of new and sophisticated simulation tools that allow simulating realistic beam transport at lowest energies through beam lines and in traps. This work was complemented by R&D into novel sensors that can measure the 3D electric field distribution. Trap experiments were carried out at several partner organizations and this resulted in publications in a number of high impact factor journals. It is expected that the improvements made within AVA will in the near future help push the resolution limits of several high precision experiments and enable further scientific breakthrough. Finally, and closely connected to the first scientific work package, cooling methods of stored particles and efficient trap injection schemes have been investigated and progress was achieved through collaboration, highlighting the central role that the network has played.
In addition to local training provided by the respective host, the network-wide training plan was successfully implemented. Trainings have included two week-long researcher skills school, a media training week leading, International Schools on Antimatter Physics and Precision Studies, Topical Workshops, and a Symposium on Accelerators for Science and Society with the training initiatives OMA on medical accelerators and LIV.DAT on data intensive science.
The AVA Fellows have had a strong involvement in all dissemination and communication activities in AVA, including the project website, the project's quarterly MIRROR newsletter, a project leaflet and brochure, as well as the film AVA – Nature (anti)matters. The AVA promotional material was used successfully to raise the profile of the project. These activities went far beyond the original plan and have reached Millions of people. Particular highlights were the Marie Curie Day 2017 (reach: 500,000), Physics of Star Wars (reach: 1,000,000), a public talk at CERN (fully booked, available only in two languages), and the AVA film with almost 100,000 views, making it the most viewed film on the EC's YouTube playlist. The project start was internationally communicated, with news articles in The Times and many other high level publications, helping raise the profile of antimatter research around the world.
