Introduction to the Future Circular Collider Study M

Introduction to the Future Circular Collider Study M. Benedikt LHC gratefully acknowledging input from FCC coordination group, global FCC design study team and all other contributors PS HE-LHC SPS FCC http: //cern. ch/fcc Work supported by the European Commission under the HORIZON 2020 projects Euro. Cir. Col, grant agreement 654305; EASITrain, grant agreement no. 764879; ARIES, grant agreement 730871; and E-JADE, contract no. 645479 photo: J. Wenninger

Summary: European Strategy Update 2013 Design studies and R&D at the energy frontier …. “to propose an ambitious post-LHC accelerator project at CERN by the time of the next Strategy update”: d) CERN should undertake design studies for accelerator projects in a global context, • with emphasis on proton-proton and electron-positron high-energy frontier machines. • These design studies should be coupled to a vigorous accelerator R&D programme, including high-field magnets and high-gradient accelerating structures, • in collaboration with national institutes, laboratories and universities worldwide. • http: //cds. cern. ch/record/1567258/files/esc-e-106. pdf Future Circular Collider Study Michael Future Benedikt Circular Collider Study Michael Benedikt Physics at FCC, 4 March 2019 2 2 2

2013 Mandate for FCC Study Scope The main emphasis of the conceptual design study shall be the long-term goal of a hadron collider with a centre-of-mass energy of the order of 100 Te. V (currently referred to as VHE-LHC) in a new tunnel of 80 -100 km circumference for the purposes of studying physics at the highest energies. The hadron collider and its detectors shall determine the basic requirements for the tunnel, surface and technical infrastructures. The corresponding hadron injector chain shall be included in the study, taking into account the existing CERN accelerator infrastructure and long-term accelerator operation plans. The performance and cost of the hadron collider shall be compared to a high-energy LHC based on the same high-field magnet technology and housed in the LHC tunnel. The conceptual design study shall also include a lepton collider and its detectors (currently referred to as TLEP), as a potential intermediate step towards realization of the hadron facility. The design of the lepton collider complex shall be based on the hadron collider infrastructure and any substantial incompatibilities with respect to the hadron collider infrastructure requirements shall be analysed and quantified. Potential synergies with linear collider detector designs should be considered. Options for e-p scenarios and their impact on the infrastructure shall be examined at conceptual level. The study shall include cost and energy optimisation, industrialisation aspects and provide implementation scenarios, including schedule and cost profiles. Future Circular Collider Study Michael Future Benedikt Circular Collider Study Michael Benedikt Physics at FCC, 4 March 2019 3 3 3

Future Circular Collider Study - Scope HE-LHC International FCC collaboration with CERN as host lab to study: • ~100 km tunnel infrastructure in Geneva area, linked to CERN • e+e- collider (FCC-ee), as potential first step • pp-collider (FCC-hh) long-term goal, defining infrastructure requirements • ~16 T 100 Te. V pp in 100 km • HE-LHC with FCC-hh technology

FCC study: physics and performance targets

Main areas for design study Machines and infrastructure conceptual designs Technologies R&D activities Planning Physics experiments detectors Infrastructure High-field magnets Hadron collider conceptual design Superconducting RF systems Hadron physics experiments interface, integration Hadron injectors Cryogenics Lepton collider conceptual design Specific technologies Safety, operation, energy management environmental aspects Planning Future Circular Collider Study Michael Future Benedikt Circular Collider Study Michael Benedikt Physics at FCC, 4 March 2019 e+ e- coll. physics experiments interface, integration e- - p physics, experiments, integration aspects 6 6 6

FCC organization and governance structure CERN DG Collaboration Board Steering Committee 1 person/inst. Advisory Committee 2 -3 persons/region Chairs: L. Rivkin (2014 -17) P. Chomaz (2018 -) 1 -2 experts/field Chairs & ECFA repres. : M. Krammer (2014 -16) P. Campana (2017 -) Chair: G. Dissertori FCC Study Coordination Hadron Collider Physics Experiments Lepton Collider Physics Experiments Future Circular Collider Study Michael Future Benedikt Circular Collider Study Michael Benedikt Physics at FCC, 4 March 2019 e-p Physics Experiments Accelerators Hadron Injectors Hadron Collider Lepton Injectors Lepton Collider Accelerator R&D Technologies Infrastructures Operation Costing Planning 7 7 7

FCC collaboration framework • A consortium of partners based on a Memorandum Of Understanding (Mo. U) • Working together on a best effort basis • Pursuing the same common goal • Self governed • Incremental & open to academia and industry • Light general framework, adapted to the needs during a conceptual design study • Detailed project descriptions in specific addenda Future Circular Collider Study Michael Benedikt Physics at FCC, 4 March 2019

FCC Kick-off Meeting Geneva http: //indico. cern. ch/e/fcc-kickoff Future Circular Collider Study Michael Future Benedikt Circular Collider Study Michael Benedikt Physics at FCC, 4 March 2019 9 9 9

EU H 2020 Design Study Euro. Cir. Col European Union Horizon 2020 program • 3 MEURO co-funding • Started June 2015, ends in May 2019 • 15 European beneficiaries & KEK & associated FNAL, BNL, LBL, NHFML Scope: FCC-hh collider key work packages • Optics Design (arc and IR) • Cryogenic beam vacuum system design including beam tests at ANKA • 16 T dipole design, construction folder for demonstrator magnets

EASITrain Marie Curie Training Network European Advanced Superconductivity Innovation and Training Network Ø selected for funding by EC in May 2017, started 1 October 2017 • • • SC wires at low temperatures for magnets (Nb 3 Sn, Mg. B 2, HTS) Superconducting thin films for RF and beam screen (Nb 3 Sn, Tl) Horizon 2020 program Electrohydraulic forming for RF structures Turbocompressor for Nelium refrigeration Magnet cooling architectures Funding for 15 Early Stage Researchers over 3 years & training 13 Beneficiaries 12 Partners I-CUBE

Status of Global FCC Collaboration 133 25 Institutes Companies Future Circular Collider Study Michael Benedikt Physics at FCC, 4 March 2019 34 EC Countries H 2020 12

FCC CDR and Study Documentation • • FCC-Conceptual Design Reports: • Vol 1 – Physics, Vol 2 – FCC-ee, Vol 3 – FCC-hh, Vol 4 – HE-LHC • Preprints available since 15 January 2019 on http: //fcc-cdr. web. cern. ch/ • CDRs accepted for publication in European Physical Journal C (Vol 1) and ST (Vol 2 – 4) Summary documents provided to EPPSU SG in December 2018 • FCC-integral, FCC-ee, FCC-hh, HE-LHC • Accessible on http: //fcc-cdr. web. cern. ch/ Future Circular Collider Study Michael Benedikt Physics at FCC, 4 March 2019

Final meeting of Euro. Cir. Col DS (H 2020 financed) Some key topics: FCC physics Studies on Tunnel Implementation and subsequent machine adaptation R&D progress on SRF and SCM Future Circular Collider Study Michael Benedikt Physics at FCC, 4 March 2019 FCC-ee : Injector chain MDI/IR optimization Machine optimisation 14

Conclusions • As recommended by the ESU 2013, the FCC study focused on the conceptual design of high-performance energy frontier circular colliders for the post-LHC era. • The FCC study was organised as an international collaboration that is growing steadily; there are many R&D opportunities and all the community is invited to join. • Baseline machine designs, with performance matching the physics requirements, were established and are documented in 4 conceptual design reports. Future Circular Collider Study Michael Benedikt Physics at FCC, 4 March 2019