<?xml version="1.0" encoding="UTF-8"?> <references> <reference> <a1>Krainer, Alexander</a1> <a2>Andreu Mu帽oz, Pablo</a2> <a2>Bartmann, Wolfgang</a2> <a2>Calviani, Marco</a2> <a2>Dutheil, Yann</a2> <a2>Lechner, Anton</a2> <a2>Nuiry, Francois-Xavier</a2> <a2>Perillo-Marcone, Antonio</a2> <a2>Ramjiawan, Rebecca</a2> <t1>Conceptual Design of the FCC-ee Beam Dumping System</t1> <t2>JACoW IPAC</t2> <sn/> <op>1753-1756</op> <vo>2022</vo> <ab>The Future Circular electron-positron Collider (FCC-ee) will feature stored beam energies of up to 18 MJ. This is a factor 100 higher than any current or past lepton collider. A safe and reliable disposal of the beam onto a beam dump block is therefore critical for operation. To ensure the survival of the dump core blocks, transversal dilution of the beam is necessary. To reduce the complexity of the system and guarantee high system availability, an optimized, semi-passive beam dumping system has been designed. The main dump absorber design has been optimized following recent studies for high energy dump block materials for the LHC High Luminosity upgrade. First simulations regarding the radiation environment of the dumping system have been carried out, allowing the definition of preliminary constraints for the integration with respect to radiation sensitive equipment. The performance of the system has been evaluated using Monte-Carlo simulations as well as thermo-mechanical Finite-Element-Analysis to investigate potential material failure and assess safety margins. An experiment at the CERN HiRadMat facility has been carried out and preliminary results show good agreement with simulations.</ab> <la>eng</la> <k1>radiation; operation; extraction; dumping; simulation; </k1> <pb/> <pp/> <yr>2022</yr> <ed/> <ul>http://cds.cern.ch/record/2839951/files/document.pdf; </ul> <no>Imported from Invenio.</no> </reference> </references>