ARIEL Buildings Construction and Electron Linac Photo-Fission Driver for the Rare Isotope Program at TRIUMF

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Baldwin Wilcox
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Canada s national laboratory for particle and nuclear physics Laboratoire national canadien pour la recherche en physique nucléaire et en physique des particules ARIEL Buildings

accélérateur de la démarche scientifique canadienne Owned and operated as a joint venture by a consortium of Canadian universities via a contribution through the National

1 Canada s national laboratory for particle and nuclear physics Laboratoire national canadien pour la recherche en physique nucléaire et en physique des particules ARIEL Buildings Construction and Electron Linac Photo-Fission Driver for the Rare Isotope Program at TRIUMF IPAC 12, 2012 May 21 Yu-Chiu Chao for e-linac team Accelerating Science for Canada Un accélérateur de la démarche scientifique canadienne Owned and operated as a joint venture by a consortium of Canadian universities via a contribution through the National Research Council Canada Propriété d un consortium d universités canadiennes, géré en co-entreprise à partir d une contribution administrée par le Conseil national de recherches Canada

2 Outline Motivation RIB science at ISAC ARIEL Civil Construction Stores & Badge Buildings Compressor Building ARIEL Targets and RIB Building E-hall renovation E-linac (the machine) E-Gun ELBT at VECC test area Cryomodules Cryogenic System HPRF Conclusion ARIEL E-linac, IPAC 12, 2012 May 21 2

ARIEL triples RIB science at ISAC New Mass Separators New Targets e-linac New Accelerators New Front End Cyclotron ISAC I ISAC II ARIEL I ARIEL II Existing 10-Year Vision: expanded RIB program with:

3 ARIEL triples RIB science at ISAC New Mass Separators New Targets e-linac New Accelerators New Front End Cyclotron ISAC I ISAC II ARIEL I ARIEL II Existing 10-Year Vision: expanded RIB program with: three simultaneous beams increased number of hours delivered per year new beam species increased beam development capabilities Implementation: Complementary electron linac driver for photo-fission New target stations and front end New proton beamline Staged installation ARIEL E-linac, IPAC 12, 2012 May 21 3

4 Site Preparation: demolition, relocation, construction 2011 October CONGESTED SITE Old Stores &RH Demolition Excavation and shoring Makes way for ARIEL building New GHe compressor building New Stores building New Badge building ARIEL E-linac, IPAC 12, 2012 May 21 4

5 New Stores Bldg Ground Breaking: 2011 March Completion: 2011 September ARIEL E-linac, IPAC 12, 2012 May 21 5

6 New Badge Building Construction started: 2011 August Occupancy: 2011 November ARIEL E-linac, IPAC 12, 2012 May 21 6

7 Helium Compressor Building Ground breaking: 2012 March Foundations: 2012 May Expect occupancy: 2012 December ARIEL E-linac, IPAC 12, 2012 May 21 7

8 ARIEL building design The culmination of an intensive study of what is needed to facilitate smooth and routine RIB delivery. ARIEL E-linac, IPAC 12, 2012 May 21 8

9 ARIEL Layout below ground RIB front end BL4N protons Target Hall Actinide Annex Cyclotron vault Tunnel Electron Hall ARIEL E-linac, IPAC 12, 2012 May 21 9

10 Excavation, Shoring, Construction Excavation started: 2011 November Tunnel Actinide Labs Target Hall RIB Annex RIB front end ARIEL site: 2012 Jan Building occupancy expected: 2013 April ARIEL site: 2012 May ARIEL E-linac, IPAC 12, 2012 May 21 10

11 Electron Hall Renovation: Cleanout Electron Hall 2010 Oct Cyclotron vault Services Annex Proton hall clean up complete 2012 Feb Construction underway 2012 March Expect occupancy 2012 October 2012 Feb ARIEL E-linac, IPAC 12, 2012 May 21 11

wall B2 up to ground for ERL/RLA operation. Final S.

12 Electron Hall Renovation: South shield wall 1st concrete pour 2012/March Shielding upgrades South wall B2 up to ground for ERL/RLA operation. Final S. wall pour, 2012/April ARIEL E-linac, IPAC 12, 2012 May 21 12

13 Electron Hall Renovation: North shield wall Poured-in-place concrete N. Wall (shield e-hall from BL4N) Rebar for N shield wall, 2012/April 1 st pour cured 2012/May ARIEL E-linac, IPAC 12, 2012 May 21 13

Installed Cryoplant for Phase I & II Accelerator: Two cryomodules Two cavities/module, 10 ma,

14 E-Linac: Accelerator Overview 300 kev thermionic gun: 650 MHz modulated NC Buncher Injector: SC Capture Cavities ARIEL Phase I: 25 MeV, 200kW 10 ma, 5-10 MeV gain 100 kw beam power Solenoid Installed Cryoplant for Phase I & II Accelerator: Two cryomodules Two cavities/module, 10 ma, 40 MeV gain 400 kw beam power ARIEL Phase II: 50 MeV, 500kW ARIEL E-linac, IPAC 12, 2012 May 21 14

15 300 kv 10 ma Electron Gun Gun assembly Detail design mostly complete Procurements in progress Installation begins: 2012 Sept HVPS SF6 Vessel Many long lead items already delivered: Ceramic, HVPS, ITX, RF Cathodes, Steering coils HV cage ARIEL E-linac, IPAC 12, 2012 May 21 15

16 Gun Components Ceramic Insulator Steering Coil Cathode Solenoid BeCu Anode ARIEL E-linac, IPAC 12, 2012 May 21 16

SF6 vessel & Gun RF modulation RF horns and ceramic waveguide

HFSS Eimac cathode rf matching network Transmission optimized at

650MHz RF power on grid used to generate duty factors 0.1% to 99.

17 SF6 vessel & Gun RF modulation RF horns and ceramic waveguide Successful dielectric waveguide R&D program with scale model & HFSS Eimac cathode rf matching network Transmission optimized at 650 MHz RF modulation on 100kV prototype makes bunched beam at 650MHz RF power on grid used to generate duty factors 0.1% to 99.9% at rep rates 100Hz to 1kHz 10µs ARIEL E-linac, IPAC 12, 2012 May

18 ELBT at VECC test stand BPM Buncher BPM BPM Diagnostic Box #1 Allison Scanner. ARIEL E-linac, IPAC 12, 2012 May 21 18

19 Test 1 Configuration screen 100kV e-gun & solenoid Slit University of Victoria View Screen Profile Monitor 300 W Faraday cup Buncher Camera Turbo ARIEL E-linac, IPAC 12, 2012 May 21 19

VECC ELBT Test1 2011 Dec/2012 Feb 0 100 120 140 160 180-0.2-0.4-0.6-0.8-1 0.95 A 0.9 A 1.0A 1.05A 1.

20 VECC ELBT Test Dec/2012 Feb A 0.9 A 1.0A 1.05A 1.1A Slit scanner profile for various solenoid settings Allison emittance scans performed 2012 Feb 09 onward up to to 660W beam power at ~20W/mm 2011 Dec 07: Image of gun electron beam ARIEL E-linac, IPAC 12, 2012 May 21 20

2011 June: focus narrowed to completion of

21 Accelerator Cryomodule Jlab style Scissor-Tuner prototype Single-cavity EINJ prototypes most features of two-cavity EACA design June: focus narrowed to completion of EINJ design, and fabrication in 2012 ARIEL E-linac, IPAC 12, 2012 May 21 Warm/cold Transition Ends 21

Injector Cryomodule Heat exchanger 4K separator Cryomodule concept borrows significantly from ISAC-II strongback 2K separator Power coupler Top loading box concept with cavity mounted to strongback

22 Injector Cryomodule Heat exchanger 4K separator Cryomodule concept borrows significantly from ISAC-II strongback 2K separator Power coupler Top loading box concept with cavity mounted to strongback that is suspended from struts Box gives headroom for on-board 2K/4K heat exchanger & 4K separator tuner cavity All procurements in hand Fabrication underway Cavity, 4K/2K insert (75% done) ARIEL E-linac, IPAC 12, 2012 May 21 22

warm/cold transition, LN2 shield Injector Cryomodule Detailing

23 Detail design complete: Cold mass support (strongback, struts), lid, cold mu-metal, scissor tuner Detail design in progress: Tank, warm/cold transition, LN2 shield Injector Cryomodule Detailing Completion milestone: ARIEL 2012 E-linac, IPAC June 12, 2012 May 1st 21 23

24 Cavity Status Success: 7 out of 7 PAVAC/TRIUMF singlecells meet requirements 7 cell Cu cavity delivered from PAVAC Nine cell cavity design fixed and contract signed Tooling optimized Four Nb half cells formed and welded ARIEL E-linac, IPAC 12, 2012 May 21 24

Cryogenic System Design/Procurement Liquid He @ 2K produced in cryo-modules by SA pumping elinac

re-liquefaction/ refrigeration loop AND 77K LN system for He pre-cool.

Dirty Helium Storage Tank OR/GMS OR/GMS, Dryer, Purifier RT gaseous He.

25 Cryogenic System Design/Procurement Liquid 2K produced in cryo-modules by SA pumping elinac Cryomodules Subatmospheric Pumping system Compressor Compressor Liquid 4K closed re-liquefaction/ refrigeration loop AND 77K LN system for He pre-cool. He Dewar Cold box Box Purity monitoring Purity monitoring (control) System Clean Helium Storage Tank Dirty Helium Storage Tank OR/GMS OR/GMS, Dryer, Purifier RT gaseous He. Emphasis on He purity White boxes: TRIUMF responsibility Pale blue boxes: cryoplant ordered from Air Liquide Advanced Technology, 2011 Oct ARIEL E-linac, IPAC 12, 2012 May 21 25

26 Helial Cold Box Supplied by ALAT Main Compressor Oil removal & Gas Management System Recovery Compressor Schedule 2013 March: ALAT cryoplant at TRIUMF 2013 October: commissioned Successful Final Design Review concluded 2012 May15 ARIEL E-linac, IPAC 12, 2012 May 21 26

27 Cryo-plant specs The plant shall demonstrate 3 modes: Mixed Mode: 4,6K and 242 L/h rising level Pure Liquefaction: 288 L/h at 4.6K in the Dewar rising level Pure Refrigeration: 600W at 4.6K in the Dewar (expected) Mixed mode point Required load line ALAT load line ARIEL E-linac, IPAC 12, 2012 May 21 27

Other major components He buffer tanks: delivery

Purifier in design stage Cold Helium Distribution

Pumps: tendere mid 2012 He heaters: prototyping He cold

rated 15 Bara Capacity ~113 m 3 each LHe Dewar

28 Other major components He buffer tanks: delivery expected 2013 Jan Dewar in hand; will widen neck He Purifier in design stage Cold Helium Distribution System: tender mid K sub-atmospheric components: Pumps: tendere mid 2012 He heaters: prototyping He cold distribution and sub-atmospheric line Cold Box Tanks rated 15 Bara Capacity ~113 m 3 each LHe Dewar Accelerator cryomodules ARIEL E-linac, IPAC 12, 2012 May Ω Resistive heater prototype 28

29 High Power RF staging: 5mA, 25 MeV in 2014 ACCELERATOR CRYOMODULE #1 300keV e-gun 5mA, 5MeV 50 kw coupler * 50 kw Couplers 5mA, 25MeV 1.3GHz NC Buncher Cavity INJECTOR CROMODULE 50 kw coupler 50 kw coupler 50 kw 30 kw Inductive Output Tube 270 kw Klystron ARIEL E-linac, IPAC 12, 2012 May 21 29

30 kw IOT Transmitter IOT transmitter will be used for EINJ beam test 2013 Jan; RF input coupler conditioning (10kW) 2012 March onward Pout & Gain 35 30 25 20 15 10 5 70 60 50 40 30 20 10 Efficiency

30 30 kw IOT Transmitter IOT transmitter will be used for EINJ beam test 2013 Jan; RF input coupler conditioning (10kW) 2012 March onward Pout & Gain Efficiency P input, mw Power Output, kw Gain, db Efficiency, % 2011 June: Tube operated tube in excess of 30kW 2011July: Successful acceptance tests: ran cw at 30 kw for 24 hours, at 25kW for 40 hours and at 20 kw for 7 days without trip. Now running routinely ARIEL E-linac, IPAC 12, 2012 May 21 30

31 Coupler Conditioning Stand in VECC test area ARIEL E-linac, IPAC 12, 2012 May 21 31

1.3 GHz 290 kw klystron & HVPS procurement Require 200kW cw for EACA

Coordinated purchase with Helmholtz Zentrum Berlin 2012 June: Final design

Feb: Tender issued 2012 March: Tender closed Vendors under consideration

32 1.3 GHz 290 kw klystron & HVPS procurement Require 200kW cw for EACA (2-cavity) cryomodule 2011 Aug: 290kW Klystron ordered from CPI, USA Coordinated purchase with Helmholtz Zentrum Berlin 2012 June: Final design review 2012 Nov: klystron factory test 600kW High Voltage Power Supply 2012 Feb: Tender issued 2012 March: Tender closed Vendors under consideration Klystron predicted CW Power Output vs. RF Input Drive ARIEL E-linac, IPAC 12, 2012 May 21 32

33 Conclusion Outstanding Progress Across All Areas Buildings Construction on schedule for 2013 April Injector Cryomodule beam test on schedule for 2013 March Accelerator Cryomodule beam test on schedule for 2014 June ARIEL E-linac, IPAC 12, 2012 May 21 33

Cavity & HOM Damping 9 cell cavity Inner 7 cells TTF geometry Modified end groups for larger coupler &HOM damping HOM frequency spectrum and shunt resistance for 9-cell cavity 78mm 96 mm Minimal

34 Cavity & HOM Damping 9 cell cavity Inner 7 cells TTF geometry Modified end groups for larger coupler &HOM damping HOM frequency spectrum and shunt resistance for 9-cell cavity 78mm 96 mm Minimal damping goal Achieved damping Ideal damping goal damper damper Two 50 kw Cornell/ CPI coupler per cavity HOM damping target set by Regenerative BBU (2-pass) 39/35/48 mm iris geometry gives the lowest maximal (Rd/Q) Q L Damping by SS ring on coupler end, CESIC ring on tuner end All modes (Rd/Q) Q L < ohm ARIEL E-linac, IPAC 12, 2012 May 21 34

35 EINJ: Injector Cryomodule Detailing ARIEL E-linac, IPAC 12, 2012 May 21 35

Electron linac photo-fission driver for rare isotope program at TRIUMF

Canada s national laboratory for particle and nuclear physics Laboratoire national canadien pour la recherche en physique nucléaire et en physique des particules Electron linac photo-fission driver for