Post on 16-Feb-2016
description
Update and Issues of the AWAKE Project at CERN
2
Outline
• Recent Evolution• Time Scale and Planning• Update and Issues for the Experimental Area• Short summary of other challenges at CERN • Summary
Edda Gschwendtner, CERN
3
Recent Evolution
E. Gschwendtner, CERN
25-26 June 2013: SPSC meetingSPSC recommends AWAKE proposal for approval.
31 July 2013: IEFC meetingPresent detailed planning and manpower needs as agreed with various groups
28 August 2013: Research BoardApproval of the AWAKE experiment
16 September 2013: Kick-Off meeting at CERN for the CERN AWAKE Project
4
CERN AWAKE Project Structure
E. Gschwendtner, CERN
WP3: Primary beam-linesChiara Bracco
CERN AWAKE ProjectProject leader: Edda Gschwendtner
Deputy: Chiara Bracco
WP4: Experimental AreaEdda Gschwendtner
WP2: SPS beamElena Chapochnikova
WP1: Project ManagementEdda Gschwendtner
A& T sector management:Engineering, Beams, Technology Departments
Injectors and Experimental Facilities Committee (IEFC)
WP1 and WP2: Depending on progress and need: dedicated meetings
WP3 and WP4: regular weekly meetings, 1-2 dedicated topics, general issues and updates
‘AWAKE Performance Meeting’: bi-weekly meetings: RP issues, electron trapping in plasma, material studies for windows, laser issues,…
5
WP1 Project Management
• Define the project responsibility matrix, the work breakdown structure, • Define the schedule and the resources (manpower and material, including spending profile)• Control the resource spending and work progress • Quality control, documentation and final acceptance• Safety file and safety officer.
Edda Gschwendtner, CERN
1 AWAKE Project Edda Gschwendtner EN/MEF1.1 Management activities (EVM, APT, MTP, EDMS, resources…) Edda, Deputy Chiara Bracco EN/MEF, TE/ABT1.2 General planning Sylvain Girod EN/MEF1.3 Safety1.4 Quality assurance Edda Gschwendtner EN/MEF1.5 Design office, materials, subcontracting, fabrication Serge Mathot EN/MME1.6 Integration Yvon Muttoni EN/MEF1.7 Coordination, Installation Ans Pardons EN/MEF1.8 Project Team meetings Edda, Chiara Bracco EN/MEF, TE/ABT1.9 Reviews-Conferences Francoise Girard-Maddoux EN/MEF
1.9.1 Review1.9.2 Conferences
Work Breakdown Structure
Issue: A fixed budget is allocated for the CERN AWAKE project. This corresponds to what we have asked for in the Design Report.
In order to have first beam in September 2016, the schedule is very tight!! Also we have to consider the general CERN schedule for the accelerators!
6Edda Gschwendtner, CERN
7
2013 2014 2015 2016 2017 2018 2019 2020
Proton beam-line
Experimental area
Electron source and beam-line
Time-Scale for AWAKE
Edda Gschwendtner, CERN
Studies, design Fabrication InstallationCom
missioning
Comm
issioning
Installation
Modification, Civil Engineering and installation
Study, Design, Procurement, Component preparation
Study, Design, Procurement, Component preparation
LS1 (Long Shutdown 1) LS218 months
Data taking Data taking
Define strategy for electron source and beam
Run-scenario NominalNumber of run-periods/year 4
Length of run-period 2 weeksTotal number of beam shots/year (100% efficiency) 162000
Total number of protons/year 4.86×1016 pInitial experimental program 3 – 4 years
8Edda Gschwendtner, CERN
2013 2014 2015 2016 2017
Cleaning; Removal of shielding, plugs,
existing equipment
Civil engineering: Electron beam and laser tunnel
Experimental area installation:Plasma cell, BI, vacuum, exp.
instrumentation, …
Installation: p-beam magnets
Install.: BI
Install.: Vacuum
Install.: Laser
Cabling
CV
Commissioning
Integration and mechanical design
End Sept. 2016:p-beam for physics
Electron beam
First Preliminary Planning for Proton Beam to Plasma
M. Bernardini, S. Girod
1st Critical Milestone:April/June 2014: start with digging!
9
WP4 Experimental Area
Work Breakdown Structure
Edda Gschwendtner, CERN
4 AWK-EXA Experimental Areas4.1 Management Edda Gschwendter EN/MEF
4.1.1 Overall coordination-management activities Edda Gschwendtner EN/MEF4.1.2 Safety4.1.3 Collaborations4.1.4 Design office, materials, subcontracting, fabrication Serge Mathot EN/MME4.1.5 Integration Yvon Muttoni EN/MEF4.1.6 Coordination, Installation, Shutdown work Ans Pardons EN/MEF4.1.7 Configuration management Sonia Bartolome Jimenez EN/MEF4.1.8 Layout database Sonia Bartolome Jimenez EN/MEF4.1.9 AWK-EXP meetings Ans Pardons EN/MEF
4.2 Secondary Electron Beam dynamics Alexey Petrenko EN/MEF4.3 Magnets Jeremie Bauche TE/MSC4.4 Power Converter Gilles Le Godec TE/EPC4.5 Beam Instrumentation Rhodri Jones BE/BI
4.5.1 Proton Beam OTR4.5.2 Electron beam instrumentation studies
4.6 Laser beam line Valentin Fedosseev EN/STI4.6.1 Optics, geometry, layout4.6.2 Interface to laser source/collaboration4.6.3 Diagnostic system4.6.4 Laser cabin
4.7 interface p/e/laser/plasma Edda Gschwendtner EN/MEF4.7.1 Electron injection inside plasma studies Alexey Petrenko EN/MEF4.7.2 Meetings Edda Gschwendtner EN/MEF4.7.3 Reports Edda Gschwendtner EN/MEF
4.8 Shielding, dumps and windows Ans Pardons EN/MEF4.8.1 Electron beam dump Ans Pardons EN/MEF4.8.2 Laser dump Ans Pardons EN/MEF4.8.3 Shutter Ans Pardons EN/MEF4.8.4 Decay tube window Ans Pardons EN/MEF4.8.5 CNGS target chamber shielding Sylvain Girod EN/MEF4.8.6 FLUKA calculations Vasilis Vlachoudis EN/STI4.8.7 Mechanical stress calculations Antonio Perillo Marcone EN/STI
4.9 Experimental equipment installation Ans Pardons EN/MEF4.9.1 equipment supports Sylvain Girod EN/MEF
4.10 Control room Sylvain Girod EN/MEF4.11 CNGS dismantling Sylvain Girod EN/MEF4.12 Vacuum system Jan Hansen TE/VSC
4.12.1 Secondary beam (p + e)4.12.2 laser beam lines
4.13 Controls Marine Gourber-Pace BE/CO4.14 Electrical Systems Thierry Charvet EN/EL
4.14.1 Low Voltage Power4.14.2 Cabling4.14.3 Experimental cabling
4.15 Cooling and Ventilation Michele Battistin EN/CV4.16 Transport and Handling Caterina Bertone EN/HE
4.16.1 Crane4.16.2 Engines for installation
4.17 Civil engineering John Osborne GS/SE4.17.1 Laser tunnel4.17.2 Electron beam tunnel4.17.3 Electron source walls
4.18 Radiation Protection Helmut Vincke DGS/RP4.18.1 RP Studies Eduard Feldbaumer DGS/RP4.18.2 General RP Helmut Vincke DGS/RP4.18.3 Environmental RP DGS/SEE
4.19 Machine Interlocks Bruno Puccio TE/MPE4.19.1 Magnet interlock Markus Zerlauth TE/MPE4.19.2 Beam interlock Bruno Puccio TE/MPE
4.20 Survey Dominique Missiaen BE/ABP4.21 Access System, doors Rui Nunes GS/ASE4.22 Alarms (fire, gas) Silvia Grau GS/ASE4.23 Ethernet, GSM Maryse da Costa, Aurelie Pascal IT/CS4.24 Commissioning Edda Gschwendtner EN/MEF4.25 Operation Edda Gschwendtner EN/MEF4.26 Dismantling4.27 Operational SW BE/OP
• Urgent issues– Preparation for CNGS area
• cleaning, emptying– Integration of experiment
– Civil engineering:• laser & electron tunnel
• Advance with other ongoing studies: – Vacuum system– Window studies
• Decay tube windows– Radiation protection studies:
• Beam losses, prompt doses, activation, radiation to electronics
– Safety files– Ventilation system
• Many more…!
10Edda Gschwendtner, CERN
Preparation of CNGS for AWAKE
CNGS
AWAKE
11
CNGS Preparation for AWAKE
Edda Gschwendtner, CERN
Today – June 2014
Yes, work has started!!
12
Layout of the AWAKE Experiment
Edda Gschwendtner, CERN
13
Removal of CNGS Shielding Plugs (~20 tons)
Edda Gschwendtner, CERN
Height not more than 1900mm. Development of special wheels for
the shielding blocks. Removal with a 30 ton tractor.
C. Bertone
14
CNGS Shielding Plugs
Edda Gschwendtner, CERN
15Edda Gschwendtner, CERN
Experimental Area
Area where electron spectrometer will be installed. Magnets, shielding, etc… will be removed.
16
Integration – Laser Scan of the Facility
Edda Gschwendtner, CERN
17
Electron Tunnel (Beginning October 2013)
Edda Gschwendtner, CERN
C. Magnier
1m
18
Electron Tunnel (Beginning December 2013)
Edda Gschwendtner, CERN
C. Magnier, F. Galleazzi
C. Magnier, F. Galleazzi
Issue:Start digging tunnel mid 2014!Define electron tunnel specs in January 2014. Specifications for electron beam must be frozen! A lot of work for integration, transport, beam
instrumentation, magnets, services, etc….
19Edda Gschwendtner, CERN
Electron Beam Tunnel
C. Magnier, F. Galleazzi
Proton tunnel1st floor: Cooling & Ventilation
Electron source
20Edda Gschwendtner, CERN
Electron Beam Tunnel
C. Magnier, F. Galleazzi
C. Magnier, F. Galleazzi
Issues:All drawings will be implemented into CERN system. Also from the experiment! Use CERN standard:
CATIA, step files!
21
Electron Source Area
Edda Gschwendtner, CERN
S. Girod, V. Clerc
PHIN injector used as baseline here. No services yet included. Tight area.
22
Electron Source Area
Edda Gschwendtner, CERN
S. Girod, V. Clerc
Issue: We need to know more about the electron source to advance with integration studies
and to consider all services needed. Space constraints! Fit the electron source to the AWAKE needs!
23
Laser Beam Line
Edda Gschwendtner, CERN
Issues:Placement of optical compressor and telescope needs to be clear before defining the exact position of the drilling. urgently needed! Vacuum components – up to 10-8 mbar?
See Mikhail’s talk, Thu 5 Dec, 9:30
24
Laser Beam Line
Edda Gschwendtner, CERN
25
Radiation Protection Studies• Accident scenarios• Plasma cell simulations
e- gallery
Accident scenario
3 mm steel 6 m long
HEH fluence per year
CNGS target chamber
He Tube1
Target Horn
He Tube2 Decay TubeBeam
Reflector
• Damage to electronics• Air activation
Issues: Consequences on material choice, shielding, geometry of plasma cell,
instrumentation and electronics Design ventilation system accordingly! Remove collimator in front of target.
See Silvia’s talk, Thu 5 Dec, 9:10
S. Cipiccia, E. Feldbaumer
26
Decay Tube Window
Edda Gschwendtner, CERN
Result: We can leave the shutter closed even when we have beam. Leave vacuum inside the decay tunnel (less air - contamination) If ever (!!) we have access during beam, OK from decay tube safety point of view.
AWAKE experiment
AWAKE beam dump
~1100m
Maximum energy deposited at decay tube window (shutter): 0.2 (2.5) J/cm3/pulse
Maximus stress in window below yield strength of Ti
Very low temperature increase in window and shutter due to beam
Decay tube: 994m long, d= 2.45m, vacuum!Decay tube window: 3mm thick Ti, d=1.4mShutter: 3cm thick iron, d=1.45m
Shutter
Steady State + 1 PulseMax Temp.= 23.875 oC
Shutter
T. Manousis, A. Perillo Marcone
27
WP3 Proton and Electron Beam Line• Proton and laser beam integration• Sector window between SPS and AWAKE Vacuum• Electron beam line design (with different parameters) • Common electron and proton beam line
Edda Gschwendtner, CERN
40 m
m
10 m
~52
mm
40 m
m
Issues: Extremely challenging with the current beam specifications to squeeze the electron
and proton beam into the plasma cell! Beam diagnostics around the plasma cell not clear. Rethink plasma cell design (size)? Or keep firm parameters for electron gun! Facility geometry gives limits to electron source design!
See Francesco’s talk, Thu 5 Dec, 8:30
See Chiara’s talk, Thu 5 Dec, 8:50
28
WP2 SPS Beam
Edda Gschwendtner, CERN
• Example of Sub-WP: RF synchronization of proton, electron, laser beam. – Electrons from RF gun driven by a laser pulse derived from same laser system as used for ionization.
Synchronization between laser pulse and electron beam at < 1ps can be achieved. – Synchronization of proton beam w.r.t. laser beam at ~100ps level is desired:
SPS RF must re-phase and lock to a stable mode-locker frequency reference from laser system.
2 AWK-SPS2.1 Management Elena Shaposhnikova BE/RF
2.1.1 Overall coordination-management activities Elena Shaposhnikova BE/RF2.1.2 Safety2.1.3 Collaborations Elena Shaposhnikova BE/RF2.1.4 Design office, materials, subcontracting, fabrication Serge Mathot EN/MME2.1.5 Integration Yvon Muttoni EN/MEF2.1.6 Coordination, Installation, Shutdown work David McFarlane EN/MEF2.1.7 AWK-SPS meetings Elena Shaposhnikova BE/RF
2.2 Beam Dynamics Elena Shaposhnikova BE/RF2.3 RF timing studies Andy Butterworth BE/RF
Work Breakdown Structure
laser pulse (30fs)proton bunch (1s ~300ns)
gasPlasmaElectron bunch (1s~5ps)
See Andy’s talk, Thu 5 Dec, 9:50Issue: Close collaboration needed with experiment, laser experts + RF, timing, beam transport…
29
Summary
• We install an experiment into an existing facility – and not a facility around an experiment! – Many constraints.– Need well-defined specifications and strategies!
• E.g. what is the strategy for the electron beam?• E.g. where will be the laser bunch compressor installed?• E.g. what is the electron spectrometer layout?
• AWAKE is an accelerator R&D experiment! – Beam is not simply delivered and the experiment is not stand-alone with its own
electronics, readout, etc…– The experiment is fully integrated into the accelerator complex
• Very close collaboration with institutes that build equipment is needed– CERN standards must be used!
• Drawings: CATIA, step-files.• Software, DAQ see Roman’s talk, Thu 5 Dec, 14:00! • Interface issues
– Advantage: profit from CERN support.
Edda Gschwendtner, CERN
30
WP3 Proton and Electron Beam Line
Work Breakdown Structure
Edda Gschwendtner, CERN
3 AWK-BTL AWAKE Beam Transfer Lines3.1 Management Chiara Bracco TE/ABT
3.1.1 Overall coordination-management activities Chiara Bracco TE/ABT3.1.2 Safety3.1.3 Collaborations Chiara Bracco TE/ABT3.1.4 Design office, materials, subcontracting, fabrication Serge Mathot EN/MME3.1.5 Integration Yvon Muttoni EN/MEF
3.1.6 Coordination, Installation, Shutdown workSylvain Girod, David McFarlane EN/MEF
3.1.7 Configuration management Sonia Bartolome Jimenez EN/MEF3.1.8 Layout database Sonia Bartolome Jimenez EN/MEF3.1.9 AWK-BTL meetings Chiara Bracco TE/ABT
3.2 Beam dynamics Chiara Bracco TE/ABT3.2.1 Proton beam line optics3.2.2 Electron beam line optics
3.3 Magnets Jeremie Bauche TE/MSC3.3.1 Proton beam magnets (refurbishment)3.3.2 Electron beam magnets (new magnets)
3.4 Power Converters Gilles Le Godec TE/EPC3.4.1 Proton beam power converters (refurbishment)3.4.2 Electron beam power converters (new PCs)
3.5 Beam instrumentation Lars Jensen BE/BI3.5.1 Proton beam instrumentation Lars Jensen BE/BI
3.5.1.1 BPMs3.5.1.2 OTRs3.5.1.3 BLMs3.5.1.4 BCTs
3.5.2 Electron beam instrumentation Lars Jensen BE/BI3.5.2.1 BPMs3.5.2.2 OTRs3.5.2.3 BLMs3.5.2.4 BCTs
3.6 Vacuum System Jan Hansen TE/VSC3.6.1 Proton beam line vacuum3.6.2 Electron beam line vacuum
3.7 Interface btw different beam-lines Chiara Bracco TE/ABT3.7.1 Laser-proton beams3.7.2 Ultrafast valves
3.8 Controls Marine Gourber-Pace BE/CO3.9 Electrical Systems Thierry Charvet EN/EL
3.9.1 Cabling proton line3.9.2 Cabling electron line
3.10 Cooling and Ventilation Michele Battistin EN/CV3.11 Transport and Handling Caterina Bertone EN/HE
3.11.1 Engines for installation3.12 Civil Engineering John Osborne GS/SE3.13 Radiation Protection Helmut Vincke DGS/RP
3.13.1 RP Studies Eduard Feldbaumer DGS/RP3.13.2 General RP Helmut Vincke DGS/RP3.13.3 Environmental RP DGS/SEE
3.14 Machine Interlocks Bruno Puccio TE/MPE3.14.1 Magnet interlock Markus Zerlauth TE/MPE3.14.2 Beam interlock Bruno Puccio TE/MPE
3.15 Survey Dominique Missiaen BE/ABP3.16 Access System, doors Rui Nunes GS/ASE3.17 Alarms (fire, gas) Silvia Grau GS/ASE3.18 Commissioning Chiara Bracco TE/ABT3.19 Operation Karel Cornelis BE/OP3.20 Dismantling3.21 Operational SW BE/OP
31
CERN Responsibilities as in the MandateCERN is host institute of the AWAKE experiment: • Design, installation, commissioning, operation, maintenance and commissioning of
the AWAKE facility, including safety matters during all phases of AWAKE, + dismantling. This includes:
– Proton and electron beam line, laser transport lines, experimental area, associated services, civil engineering.
– Necessary modifications of the civil engineering and general services of the AWAKE facility.
– Optimization of the beam parameters. Production of the AWAKE proton beam in the SPS and in the transfer to the experimental area, within specifications.
– Electron beam studies in the plasma cell.– Development of the diagnostic instrumentation along the beam lines and in the
experimental area. – The coordination and installation of the experimental equipment delivered by the
collaboration, including interface design and construction support.– The coordination of all radiation protection and safety aspects.– Coordinate the studies of all interfaces between the different systems (plasma cell,
electron beam, proton beam, laser…), including studies on the measurement program– Take responsibility for all safety aspects. Prepare safety files. – Evaluate dismantling feasibility.
Edda Gschwendtner, CERN