Date post: | 02-Jan-2016 |
Category: |
Documents |
Upload: | cora-flores |
View: | 36 times |
Download: | 0 times |
Status and Future Perspective of the HIE-ISOLDE Project
IBS-RISP @ CERN, November 19-20, [email protected]
OUTLINE
2
Scope of HIE-ISOLDE
Upgrade of ISOLDE Facility: HIE-ISOLDE
R&D Activities
Outlook for 2012
3
ISOLDE: the ISOL-type RIB facility at CERN
Pulsed 1.4 GeV Proton beam
Courtesy D. Voulot
4 Courtesy F. Wenander
5
Motivation
The High Intensity and Energy (HIE) ISOLDE project builds on the success of the REX-ISOLDE post-accelerator and will focus on the upgrade of the REX facility but also aims to improve the target and front-end part of ISOLDE to fully profit from upgrades of the existing CERN proton injectors (LINAC4 and PSB Upgrade):
Higher energy for the post-accelerated radioactive
beam
More beams (Intensity wise and different species)
Better beams (High purity beams, low emittances,
more flexibility in the beam parameters)
6
HIE-ISOLDE aims at increasing the energy of these RIB up to 10A MeV and their intensity by a factor 10
Energy Upgrade:The HIE-ISOLDE project concentrates on the construction of the SC LINAC and associated infrastructure in order to upgrade the energy of the post-accelerated radioactive ion beams to 5.5 MeV/u in 2015 and 10 MeV/u by 2016
Intensity Upgrade:The design study for the intensity upgrade, also part of HIE-ISOLDE, starts in 2012, and addresses the technical feasibility and cost estimate for operating the facility at 15 kW once LINAC4 and PS Booster are online.
7
NuPECC Long Range Plan 2010 Timeline for RIB Facilities
8
Superconducting LINAC installed in Three Phases
3 stages installation 1.2 MeV/u
3 MeV/u
5.5 MeV/u
10 MeV/u
Now
2014
2016
>2017
9
HIE-ISOLDE SC LINAC
10
R&D activities (2008 – 2011)
Proposed stage 1 HEBT layout
Latest HEBT design – stage 2bAll details on EDMS (HIE-ISOLDE/HEBT LINES OPTICS AND LAYOUT) Drawings, layout tables and (new) madx reference optics files
13
Planning
?
?
14
Civil EngineeringCompressor and Cold Box Building
Civil Engineering finished summer 2012
Autumn 2012 !
B. 170
B. 198B. 199
Racks sub systems
Electrical systems: Oct 2012 – June 2013
16
Cooling & Ventilation
Cooling & Ventilation: Oct 2012 – June 2013
B. 199 cold box buildingB. 198 compressor building
Experimental hall 170
17
Modular Linac & Cryo LineCourtesy: Stephane Maridor
Cryo Cold Line- stage 1: January 2014 – June 2014
20155.5MeV/u
Linac CM 1&2 - stage 1: August 2014 – October 2014
Sep 2014 – Feb 2015
18
Cryo Cold Line- stage 2
Modular Cryo Line
Linac CM High-β 1,2,3&4 - stage 2a
Courtesy: Stephane Maridor
2016 ?10MeV/u
19
Cryo Cold Line- stage 2
Modular Cryo LineCourtesy: Stephane Maridor
2017 ?
Linac CM High-β 1,2,3 & 4, Low-β 1&2 - stage 2b
Chopper Line
and Chopper Line
Call for Letters of Intent (deadline May 21 2010)
• 34 Letters submitted• 284 Participants from 76 Laboratories in 22 Countries• 30 LOIs make use of the Energy and Intensity
increases; 4 of the intensity upgrade only • Major mechanisms are Coulex (13) and transfer(16); elastic scattering(3); fission(2)• (3) letters concern masses and moments; (4)
astrophysics and (5) major new instrumentation• Major subjects: Nuclear shapes ; Shell evolution; Halo
properties; Nuclear astrophysics
Miniball + T-REX• Segmented Ge array • Inner Si-strip detection for charged
particles (T-REX)• No show stopping beam requirements
but would benefit from slow extraction and buncher/chopper
setup Geometrical properties
Energy properties(FWHM values)
Timing Power
MINIBALL
(+general purpose reaction chamber)
<3mrad + 2-3mm FWHM diameter (at 5-10 MeV/u energy)*
En. Spread: <1e-3
En. Accuracy: <1%
En. Stability: ?
Would profit from microstructure required by HELIOS
About 26 kW
Helios
• Solenoid for transfer reactions
• Needs buncher/chopper for TOF measurement with 2 ns resolution
setup Geometrical properties
Energy properties(FWHM values)
Timing Power
HELIOS 3mrad + 5mm FWHM diameter at 5-10 MeV/u
En. Spread: <1e-3
En. Accuracy: <1%
En. Stability:
Important (for 10MeV/u):
resolution <2ns on target
repetition rate: 1/100 ns
no background (<1% acceptable)
below 25 kW
ACTAR
• Active target for resonant scattering and transfer reactions
• Allows to measure with very low intensities
setup Geometrical properties
Energy properties(FWHM values)
Timing Power
ACTAR
(input: R. Raabe)
<2 mrad + 3mm FWHM diameter at 5-10 MeV/u*
En. Spread: <1e-2
En. Accuracy:
En. Stability:
About 25 kW
24
BUDGET
25
OUTLOOK Civil Engineering Works completed
Installation of Main Services (EL, CV, others)
Decision on the procurement of Cryogenic Plant (FC Dec. 2012)
Ready to launch procurement of first batch of high-beta cavities => via CATE + others
Ready to launch procurement of CM1 and CM2 => via CATE
Ready to launch procurement of HEBT phase-1
Cost and Schedule Review (22-23 Nov. 2012)
26
Thank you
HIE-ISOLDE web site -> http://hie-isolde.web.cern.ch/hie-isolde/
CATHI-ITN web site -> https://espace.cern.ch/Marie-Curie-CATHI/default.aspx
27
Acknowledgements
The ISOLDE CollaborationThe HIE-ISOLDE Project Team and groups within CERN Accelerator and Technology SectorThe Swedish Knut and Alice Wallenberg Foundation (KAW 2005-0121) The Belgian Big Science program of the FWO (Research Foundation Flanders) and the Research Council K.U. Leuven The CATHI Marie Curie Initial Training Network: EU-FP7-PEOPLE-2010-ITN Project number 264330.The Spanish Programme “Industry for Science” from CDTI
HIE-ISO
LDE Project
1. Project Management
2. Linac Systems
4. Installation&
Commissioning
3. Infrastructure&
Integration
8.3 Access System GS/ASE
8.2 Radioprotection DG/SCR
HIE-LIN
ACD
esign Study
5. Target Study
6. Target Area and Class-A Lab Integration
7. Injection & Beam distribution
8.4 Access System GS/ASE
8. Safety
2.1 Cavity RF BE/RF
2.2 Cavity Design manufacturing EN/MME TE/VSC
2.3 Beam dynamics BE/RF-ABP
2.4 Cryomodules TE/MSC EN/MME
2.5 Beam Instrumentations BE/BI
2.6 SC Solenoid TE/MSC
2.7 Beam transfer line (magnets) TE/MSC
2.8 Linac Integration EN/MEF2.9 Vacuum TE/VCS2.10 Survey BE/ABP
3.4 Electrical systems EN/EL
3.5 Cryogenic system TE/CRG
3.6 Power converters TE/EPC
3.7 Industrial Control system EN/ICE
4.1 Single cavity test BE/RF
4.2 Cryomodule test BE/RF
4.3 Transport & Handling EN/HE
3.8 Beam Control system BE/CO
5.1 Target design EN/STI-HE
5.2 Front Ends EN/STI TE/EPC-ABT
5.3 Beam Diagnostics BE/BI
6.1 Layout upgrade EN/MEF
6.2 Cooling and ventilation EN/CV
6.3 Electrical systems EN/EL
6.4 Vacuum TE/VCS
6.5 Survey BE/ABP
6.6 Civil engineering GS/SEM
6.7 LL Control system EN/STI
7.1 Off line separator EN/STI
7.2 Separator areas EN/STI
7.3 Experiment Hall EN/MEF
7.4 Beam lines BE/ABP
Steering Committee International Advisory Panel
8.1 Safety Coordinator GS/DI
3.1 Civil Engineering GS/SEM3.2 Integration EN/MEF3.3 Cooling ventilation EN/CV
3.9 Interlocks TE/MPE
4.4 Planning & Installation EN/MEF
4.5 Linac commissioning BE/RF-OP
1.1 Project Leader – Y. Kadi (EN/HDO)
1.2 Project Safety Coordinator – A.P. Bernardes
1.3 Technical Coordinator – M. Pasini BE/RF
1.4 Design Study Coordinator–R.Catherall EN/STI
1.5 Budget and Planning – E.Delachenal EN/GMS
1.6 Administration – E. Cochet EN/GMS
Work Breakdown Structure
29
Acknowledgements
International Collaboration
I. Goulas
International Advisory Panel
A. Bracco
Steering Committee
M. Huyse
Physics CoordinationMaria Garcia-Borge
Linac System
W. Venturinia
Design Study
R. Catherall
SafetyA.P. Bernardes
SafetyWorking Group
Design Study
Working Group
Linac Commissio
ningWorkingGroup
Cryo-modulesWorkingGroup
RFAccelerati
ngWorkingGroup
BeamDynamicsWorkingGroup
Technical Coordination
Y. Kadi
Project ManagementY. Kadi
Infrastructure &
IntegrationWorking
Group
Infrastructure&
IntegrationE. Siesling
High-EnergyBeam
Transfer WG
PhysicsWorking Group
Research Training Themes Addressed by the CATHI Proposal
(56 FTE over 4 years)
Y. Kadi HIE-ISOLDE Proposal, IEFC, August 21, 2009HIE-ISOLDE General Meeting, 19 March 2010 30