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During the decade ahead researchers are going to build on tackling the big questions: how did matter in the Universe evolve into what we see today and whether this knowledge can be used to help solve energy, health and environmental problems.
"Nuclear physics projects are 'big science', with large investments and long lead times that need careful planning and strong political support," said Guenther Rosner, Chair of the Nuclear Physics European Collaboration Committee (NuPECC) of the ESF.
"We can already see where Europe needs to be targeting funds to stay at the forefront. In particular, we need to both upgrade our major facilities and invest in new central research infrastructures offering more intense antimatter and rare isotope beams."
The report details three major routes forward for nuclear physics, all of which will require powerful new accelerator facilities. It proposes a concrete roadmap for upgrading existing, and building new, powerful nuclear physics facilities so that funding agencies can target their support.
Rosner comments: "This is an immensely important and challenging task that requires the effort of both theoretical and experimental scientists, funding agencies, politicians and the public."
Nuclear technology offers a source of low-carbon energy as well as its use in medical diagnosis and cancer therapy, security detectors, materials studies and artefact analysis.
Nuclear physics trains people in advanced techniques that are transferred to these industries. Enhancing this skills base will ensure that these organisations continue to have access to the expertise they need.
The 'NuPECC Long Range Plan 2010 - Perspectives of Nuclear Physics in Europe' results from a collaboration of the entire European nuclear physics community. It is available online,
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