1. Welcome to CERN
Volker Mertens
CERN Technology Department

2. Workshop
on potential collaboration with FIML in the framework of the FCC study (following up from a visit at FIML, Dortmund, on 23 June 2016)
Programme
22 November 2016
study

3. Workshop Programme 23 November 2016

4. Future Circular Collider StudyPS
FCC
LHC
SPS
Work supported by the European Commission under the HORIZON 2020 project EuroCirCol, grant agreement

5. CERN
CERN, the European Organization for Nuclear Research, is an intergovernmental organisation which was founded in 1954 ( It has meanwhile 21 Member States. Its seat is in Geneva; its premises are located on both sides of the French-Swiss border.
CERN’s mission is to enable international collaboration in the field of high-energy particle physics research. To this end it designs, builds and operates particle accelerators and the associated experimental areas. At present more than scientific users from research institutes all over the world are using CERN’s installations for their experiments.
The accelerator complex at CERN is a succession of machines with increasingly higher energies. Each machine injects the beam into the next one, which takes over to bring the beam to an even higher energy. The present flagship of this complex is the Large Hadron Collider (LHC;

6. Chain of accelerators

7. Pre-accelerators LINAC2 PS Booster Proton Synchrotron
Super Proton Synchrotron

8. LHC Large Hadron Collider Magnet Coil LHC interconnection
Present flagship
27 km circumference, 100 m underground.
LHC interconnection

9. Detectors
ATLAS

10. Data processing

11. High-Energy Physics (HEP)
“Standard model” describes only 5 % of the universe !
What is dark matter ?
What is dark energy ?
Why is there more matter than antimatter ?
Why do the masses differ by more than 13 orders of magnitude ?
Do fundamental forces unify in single field theory ?
What about gravity ?
Is there a “world equation” – a “theory of everything” ?
Known Matter 4.9%
Dark Matter
26.8%
Dark Energy 68.3%
galaxy rotation curves, Zwicky
Largely dominated by the unknown.
K. Borras

12. Roads to discoveries Higher Energy Higher Luminosity Smaller Scales
Rare Processes
Higher energy = access to higher masses (Einstein) and better resolution (de Broglie)
Higher Energy
Higher Luminosity

13. Strategic motivation for FCC
European Strategy for Particle Physics 2013:
“…to propose an ambitious post-LHC accelerator project….., CERN should undertake design studies for accelerator projects in a global context,…with emphasis on proton-proton and electron-positron high-energy frontier machines….coupled to a vigorous accelerator R&D programme, including high-field magnets and high-gradient accelerating structures,….”
U.S. strategy and P5 recommendation 2014:
”….A very high-energy proton-proton collider is the most powerful tool for direct discovery of new particles and interactions under any scenario of physics results that can be acquired in the P5 time window….”
ICFA statement 2014:
”…. ICFA supports studies of energy frontier circular colliders and encourages global coordination.….”

14. Pushing the energy frontier
A very large circular hadron collider seems the only approach to reach 100 TeV c.m. collision energy in coming decades
Access to new particles (direct production) in the few TeV to 30 TeV mass range, far beyond LHC reach.
Much-increased rates for phenomena in the sub-TeV mass range → increased precision w.r.t. LHC and possibly ILC
Hadron collider energy reach
compared to LHC factor ~4 in radius, factor ~2 in field  O(10) in Ecms
𝐸∝ 𝐵 𝑑𝑖𝑝𝑜𝑙𝑒 ×𝜌 𝑏𝑒𝑛𝑑𝑖𝑛𝑔

15. Future Circular Collider Study
GOAL: CDR and cost review for the next ESU (2018)
FCC-hh baseline
100 km, 16 T
100 TeV (c.o.m.)
10000 t Nb3Sn
FCC-hh
80 km, 20 T
100 TeV (c.o.m.)
2000 t HTS
8000 t LTS
Geneva PS
HE-LHC baseline
27 km, 16 T
26 TeV (c.o.m.)
2500 t Nb3Sn
SPS
LHC
LHC
27 km, 8.33 T
14 TeV (c.o.m.)
1300 t NbTi

16. accelerator + infrastructure
Scope:
accelerator + infrastructure
FCC-hh: 100 TeV pp collider as long-term goal  defines infrastructure needs
FCC-ee: e+e- collider, potential intermediate step
HE-LHC: based on FCC-hh technology
key technologies pushed in dedicated R&D programmes, e.g.
16 Tesla magnets for 100 TeV pp in 100 km
SRF technologies and RF power sources
tunnel infrastructure in Geneva area, linked to CERN accelerator complex;
site-specific, as requested by European strategy

17. Scope: physics + experiments
physics opportunities
discovery potentials
experiment concepts for hh, ee and he
machine Detector Interface studies
concepts for worldwide data services
overall cost model;
cost scenarios for collider options
including infrastructure and injectors;
implementation and governance models

18. Timescale
1980
1985
1990
1995
2000
2005
2010
2015
2020
2025
2030
2035
2040
Constr.
Physics
LEP
Design
Proto
Construction
Physics
LHC
Design
Construction
Physics
HL-LHC
20 years
Design
Physics
Construction
Proto
FCC study
Now is the right time to plan for the period 2035 – 2040
Goal of phase 1: CDR by end 2018 for next update of European Strategy

19. Study timeline to CDR
2014
2015
2016
2017
2018 Q1 Q2 Q3 Q4
Study plan, scope definition
Explore options
conceptual study of baseline develop baseline <|> detailed studies
FCC Week 2015:
work towards baseline
FCC Week 17 & Review Cost model, LHC results  study re-scoping?
FCC Week 2016
Progress review
Elaboration,
consolidation
FCC Week 2018
 contents of CDR
Report
CDR ready

20. International Collaboration
88 institutes
28 countries + EC
Status: August, 2016

21. 87 collaboration members + EC + CERN as host
Collaboration Status
87 collaboration members + EC + CERN as host
ALBA/CELLS, Spain
Ankara U., Turkey
Aydin U, Istanbul, Turkey
U Belgrade, Serbia
U Bern, Switzerland
BINP, Russia
CASE (SUNY/BNL), USA
CBPF, Brazil
CEA Grenoble, France
CEA Saclay, France
CIEMAT, Spain
Cinvestav, Mexico
CNRS, France
CNR-SPIN, Italy
Cockcroft Institute, UK
U Colima, Mexico
UCPH Copenhagen, Denmark
CSIC/IFIC, Spain
TU Darmstadt, Germany
TU Delft, Netherlands
DESY, Germany
DOE, Washington, USA
TU Dresden, Germany
Duke U, USA
EPFL, Switzerland
UT Enschede, Netherlands
ESS, Sweden
U Geneva, Switzerland
Giresun U. Turkey
Goethe U Frankfurt, Germany
GSI, Germany
GWNU, Korea
U. Guanajuato, Mexico
Hellenic Open U, Greece
HEPHY, Austria
U Houston, USA
ISMAB-CSIC, Spain
IFAE, Spain
IFIC-CSIC, Spain
IIT Kanpur, India
IFJ PAN Krakow, Poland
INFN, Italy
INP Minsk, Belarus
U Iowa, USA
IPM, Iran
UC Irvine, USA
Isik U., Turkey
Istanbul University, Turkey
JAI, UK
JINR Dubna, Russia
Jefferson LAB, USA
FZ Jülich, Germany
KAIST, Korea
KEK, Japan
KIAS, Korea King’s College London, UK
KIT Karlsruhe, Germany
KU, Seoul, Korea
Korea U Sejong, Korea
U Liverpool, UK U Lund, Sweden
U Malta, Malta
MAX IV, Sweden
MEPhI, Russia
UNIMI, Milan, Italy
MIT, USA
Northern Illinois U, USA
NC PHEP Minsk, Belarus
OIU, Turkey
Okan U, Turkey
U Oxford, UK
PSI, Switzerland
U. Rostock, Germany
RTU, Riga, Latvia
UC Santa Barbara, USA
Sapienza/Roma, Italy
U Siegen, Germany
U Silesia, Poland
Stanford U, USA
U Stuttgart, Germany
TAU, Israel
TU Tampere, Finland
TOBB, Turkey
U Twente, Netherlands
TU Vienna, Austria
Wigner RCP, Budapest, Hungary
Wroclaw UT, Poland

22. 468 168 Institutes 24 First FCC Week Conference Washington DC
23-27 March 2015
468
Participants
168 Institutes 24
Countries

23. Summary status
Consolidated parameter sets for FCC-hh and FCC-ee machines
Complete optics baselines for FCC-hh and FCC-ee, beam dynamics compatible with parameter requirements
Common footprint for both accelerator options
Convergence on main MDI parameters and detector studies
First round of geology and implementation CE and TI studies completed
Full design iteration for next FCC Week conference in May 2017
Next milestone is a study review at FCC Week to confirm baseline and define contents of the Conceptual Design Report.