NA2: Thin actinide targets optimized for high intensity beams

1. NA2: Thin actinide targets optimized for high intensity beams Purpose: Optimize the high power capability and durability of thin actinide targets (“thin” means 0.1 to few mg/cm2, i.e. not ISOL targets) for neutron and charged-particle induced reactions. Benefits: Extended target lifetimes and increased primary/secondary beam intensities at existing European user facilities (LOHENGRIN@ILL, SHIP@GSI, TASCA@GSI, LISE@GANIL,...). Organisation: Coordinated production and test of fissile and non-fissile actinide targets under reproducible conditions. Comparison of different target preparation techniques, backings and covers. Training activities: • Workshop on thin actinide targets. • Permanent link between target producers and target users. • Hands-on experience for students and postdocs.

2. NA2 Participant Institutions 1. Institut Laue Langevin & LPSC Grenoble, F target production by electrolysis, electrodeposition and painting on-line target tests under intense neutron flux to measure temperature, fission product intensity and energy distribution 2. IRMM Geel, B target production by spray-painting, electrodeposition (and evaporation) 3. LMU Munich, D target production by evaporation (and sputtering) 4. IPN Orsay, F target production by electrodeposition, spray painting target characterization by RBS, alpha, gamma spectroscopy future: CACAO project: joint CNRS-IN2P3/CEA hot lab 5. GANIL Caen, F heavy ion irradiation for validation of dpa-lifetime-relation Target production in collaboration with Nuclear Chemistry Institute Mainz, LBL Berkeley and Radium Institute St. Peterburg. Open to other collaborators.

3. NA2: Actinide target production and characterization IRMM LMU LMU IPNO IRMM 235U target RBS cartography (1.5 mm step)

4. Additional losses due to: • sputtering by fission products • evaporation (e.g. for UF4) • diffusion into backing or cover • loss of adhesion to backing NA2: On-line test of high power actinide targets l = F s Burnup of 235U target in 5.5E14 n/cm2/s neutron flux comparison to accelerator beams: 5.5.1014 n/cm2/s ≈ 88 pmA/cm2 • target thickness monitored on-line via width of fission product energy distribution • target temperature distribution monitored by pyrometer and IR camera • longterm studies (several weeks) possible simulate at LOHENGRIN long exposition to intense HI beams

5. NA2: Synergies with other NA or JRA “survival training” for actinide targets at ILL: • veryhigh neutron flux: 5.5E14 n/cm2/s • nuclear heating up to ca. 1000 °C • extremely high radiation damage: ca. 50 dpa/day, equivalent to damage by 3 mA/cm2 340MeV 48Ca beam on 238U target, i.e. 100 times more intense than present accelerator beams We identified overlap/possible synergies with the following other LoIs: • ShERN (NA12) • ECOS (NA4 or JRA11) • ISOL-AT (JRA1) We are ready to merge our LoI and contribute with our capabilities to any of these. We leave the decision to the EURONS2-proposal management team to select the best option for fitting it into the overall EURONS2 proposal.

6. The LOHENGRIN fission fragment separator mass-separated fission fragments, up to 105 per second, T1/2 ≥ microsec. flux 5.5·1014 n./cm2/s few mg fission target (0.1-1 mg/cm2, few cm2) several 1012 fissions/s