status of the high current proton accelerator for the ...epaper.kek.jp/e02/talks/thbla002.pdfstatus...
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Status of the High Current Proton Accelerator for the TRASCO Program
Paolo PieriniINFN Milano - LASA
on behalf of the TRASCO_ACC group
EPAC 2002 Paris, 3-7 June 2002
TRASCO_ACCD. Barnia, G. Bellomoa, G. Bisoffib, A. Bosottia, L. Celonac, A. Chincarinid, G. Ciavolac, M. Comunianb, A. Faccob, S. Gamminoc, G. Gemmed, G. Lamannae, A. Lombardib, P. Michelatoa, M. Napolitanof, C. Pagania, A. Palmierib, R. Parodid, P. Pierinia, A. Pisentb, F. Scarpab, D. Sertorea, V. Zviagintsevb,
aINFN Milano LASA http://wwwlasa.infn.itbINFN-LNL http://www.lnl.infn.itcINFN-LNS http://www.lns.infn.itdINFN Genova http://www.ge.infn.it eINFN Bari http://www.ba.infn.itfUniversity and INFN, Napoli http://www.na.infn.it
P. Pierini EPAC 2002, Paris, 3-7 June 2002 2
The TRASCO Program
TRASCO: conceptual study and the prototyping of components for an accelerator driven system for nuclear waste transmutation, and involves research agencies and Italian companies
TRASCO/ACC Accelerator studies: lead by INFN
TRASCO/SS Subcritical reactor studies: lead by ENEA
TRASCO/ACC (1998-2004, in three funding stages) is devoted to: Conceptual design of a high current superconducting proton linac
I=30 mA, E = 1 GeV Construction and R&D activities on key items:
an 80 kV, 35 mA proton source (INFN - LNS) a 5 MeV, 30 mA, CW RFQ (INFN - LNL) SC cavity prototypes for low β cavities (<100 MeV) (INFN - LNL) SC cavity prototypes for β = 0.47 elliptical cavities (INFN - MI) SC cavity prototypes for β = 0.85 sputtered cavities (INFN - GE) engineering of elliptical SC linac components (cryomodules, etc.) (INFN - MI)
P. Pierini EPAC 2002, Paris, 3-7 June 2002 3
Beam Dynamics
The Reference Linac Design
3 section linac: 85/100 - 200 MeV, β=0.47 200 - 500 MeV, β=0.65 500 1000/2000 MeV, β=0.85
Five(six) cell elliptical cavitiesQuadrupole doublet focussing: multi-cavity cryostats between doublets
704.4 MHz
5 - 85/100 MeV SC linac
Baseline design:Reentrant cavities (352 MHz)
Alternative design:Spoke, λ/2, λ/4, ladder
8βλ FODO focussing with sc magnets
High transm
ission 95%30 m
A, 5 M
eV(352 M
Hz)
Microwave
RF SourceH
igh current (35m
A)
80keV
High Energy SC LinacISCLRFQSource
Proton Source RFQ Medium energy ISCL linac 3 sections high energy SC linac
80 keV 5 MeV ~100 MeV 200 MeV 500 MeV >1000 MeV
P. Pierini EPAC 2002, Paris, 3-7 June 2002 4
TRIPS: TRASCO Intense Proton Source
High intensity (tens mA) proton sources exist Chalk River, Los Alamos, CEA-Saclay
ADS asks for high reliability and availabilityAdditional efforts are required for:
Voltage and current stability Control of the low beam emittance
Design in 1999, source in LNS in May 2000Achievements:
First beam of 20 mA @ 60 kV in Jan 2001 80 kV, 55 mA operation in Aug 2001
Off-resonance microwave discharge source (2.45 GHz), based on SILHI (CEA/Saclay)
80 kV
To be measured
55 mA (~90% p.f.)
Achieved
80 kVOperating voltage
0.2 π mm mradBeam emittance
35 mAProton Beam current
TRIPS Goals:
Reported at EPAC2000, PAC2001
P. Pierini EPAC 2002, Paris, 3-7 June 2002 5
2 kW RF generator
Plasma chamber
Layout of the Source and LEBT
Extraction electrodes
Studies on SILHI extraction system lead to: Pentode
configuration with new geometry
Lowered voltage: from 95 kV to 80 kV
P. Pierini EPAC 2002, Paris, 3-7 June 2002 6
2 kW RF generator
Plasma chamber
Layout of the Source and LEBT
Extraction electrodes
Studies on SILHI extraction system lead to: Pentode
configuration with new geometry
Lowered voltage: from 95 kV to 80 kV
Matching transformer (impedance match)
Moving coils to adjust ECR region
4-step binomial transformer for waveguide to plasma impedance matching
P. Pierini EPAC 2002, Paris, 3-7 June 2002 7
Performances and recent development
A rms emittance below 0.2 π mm mrad has been calculated with beam dynamics simulations, crosschecking different codes
Emittance unit from CEA is being shipped to Catania for measurementsLEBT for beam analysis and characterization:
Solenoid (focussing) Beam alignment monitor 2 current transformers for beam current measurements 10 kW beam stop
Reliability tests have been performed: at 65 kV/15 mA: 24 h with no beam
interruptions Tests at 80 kV are underway (improving)
A new control system for automatic restart procedures after discharge is being implemented
10 kW beam stop
LEBT line
P. Pierini EPAC 2002, Paris, 3-7 June 2002 8
Low Energy Linac
The low energy linac is split in two components: A normal conducting CW Radio Frequency Quadrupole (RFQ): from 80 keV
to 5 MeV RFQ design: 3 resonantly coupled segments. Modulation:
Radial match in the structure Shaper Gentle buncher (from dc to 352.2 MHz bunches) Accelerator (boosts up to 5 MeV, longest portion)
A superconducting linac (ISCL): from 5 MeV to 100 MeV Reentrant cavities for highest availability (allowing beam on with 1 cavity off) λ/4, λ/2 cavities Spoke cavities
Papers contributed to this Conference (TU and TH)Papers contributed to this Conference (TU and TH)
coupling cells
wave guide RF loop
7.13 mtechn. model
tuners wave guide vacuum ports RF loop
P. Pierini EPAC 2002, Paris, 3-7 June 2002 9
RFQ Design
Different optimization procedure for TRASCO RFQ w.r.t. LEDA Limit to 1 RF source (1.3 MW CERN-LEP klystron) Lower design current of 30 mA (transmission of 96%) Peak surface electric field is 33 MV/m, 1.8 Kilpatrick limit Simplified engineering/manufacturing choices
Substantial heat dissipation in the structure ~ 600 kW totalThree resonantly coupled segments
1.8 KilpatrickPeak Field
600 kW (structure)
150 kW (beam)RF Power
7.13 m (3 sections)Length
0.2 π mm mrad TBeam emittance
5 MeVFinal Energy
0.18 π deg MeV L
30 mA (96 % transmission)Beam current
TRASCO RFQ:
Poster THPLE083: Field tuning of the TRASCO RFQ
Poster THPLE083: Field tuning of the TRASCO RFQ
P. Pierini EPAC 2002, Paris, 3-7 June 2002 10
RFQ Design
Different optimization procedure for TRASCO RFQ w.r.t. LEDA Limit to 1 RF source (1.3 MW CERN-LEP klystron) Lower design current of 30 mA (transmission of 96%) Peak surface electric field is 33 MV/m, 1.8 Kilpatrick limit Simplified engineering/manufacturing choices
Substantial heat dissipation in the structure ~ 600 kW totalThree resonantly coupled segments
1.8 KilpatrickPeak Field
600 kW (structure)
150 kW (beam)RF Power
7.13 m (3 sections)Length
0.2 π mm mrad TBeam emittance
5 MeVFinal Energy
0.18 π deg MeV L
30 mA (96 % transmission)Beam current
TRASCO RFQ:
Poster THPLE083: Field tuning of the TRASCO RFQ
Poster THPLE083: Field tuning of the TRASCO RFQ
Copper dominated Not space charge limited Not beam loading limited 150 kW to beam 600 kW to copper
P. Pierini EPAC 2002, Paris, 3-7 June 2002 11
RFQ: fabrication tests
A 3 m Al model of the structure has been built and measured at LNL, and achieved the necessary field stabilizationA 220 mm part of the structure has been built to test the full fabrication procedures
Brazing Water channels by long (1 m) drilling
Full structure is under fabrication
P. Pierini EPAC 2002, Paris, 3-7 June 2002 12
Superconducting low energy linac
Single or two-gap structure linac Moderate energy gain/cavity Solid state RF amplifiers 8 βλ focussing lattice
Various options, are being considered Reentrant cavities Spoke cavities λ/4 cavities ladderQuarter Wave resonator (QWR) 2 gap structure of the ALPI linac in INFN-LNL
Reentrant cavity single gap structure. He Vessel integrated in the cavity2 gap spoke cavity
Poster THPDO022: RF testing of the TRASCO SC Reentrant Cavity for High Intensity Proton Beams
Poster THPDO022: RF testing of the TRASCO SC Reentrant Cavity for High Intensity Proton Beams
Poster TUPLE121: A 2.5 kW, Low Cost 352 MHz Solid State RF Amplifier for CW and Pulsed Operation
Poster TUPLE121: A 2.5 kW, Low Cost 352 MHz Solid State RF Amplifier for CW and Pulsed Operation
4βλ
tuning
F D
4βλ
P. Pierini EPAC 2002, Paris, 3-7 June 2002 13
The high energy linac
Designed with high current beam dynamics criteria to avoid emittance growth (smooth, tune resonances, ...)
655# cells/cavity
1 GeV480 MeV190 MeV
12.3 MV/m10.2 MV/m8.5 MV/mMax. Eacc (MV/m)
484824# cavities in section
12
8.5 m
480 MeV
102 m
0.85
16
5.8 m
190 MeV
93 m
0.65
12# periods
4.2 mDoublet period
100 MeVInitial/Final Energy
0.47Section β
50 mLength
Conceptual design of the 3 section linacDevelopment and test of prototype cavities
At 352 MHz with the LEP II sputtering technology At 704 MHz, bulk niobium, for the lowest β
Design and engineering of cavity components and ancillaries Cryomodule, tuner system, piezo damping,
RF Test infrastructure
Papers contributed to this Conference (WE and TH)Papers contributed to this Conference (WE and TH)
Clean room and HPR
UPurewater
RF Test Bunker
P. Pierini EPAC 2002, Paris, 3-7 June 2002 14
Conceptual design: cavity design
Parametric tool for the analysis of the cavity shape on the electromagnetic (and mechanical) parametersInner cell tuning is performed through the diameter, all the characteristic cell parameters stay constant: R, r, α, d, L, RirisEnd cell tuning is performed through the wall angle inclination, α,or distance, d. R, L and Riris are set independentlyEnd groups for a 4 die cavity can be tuned using the end cell diameter (and a,d,R,L, Riris are set independently)
βg = 0.81 Cavity for SNS 4 dies
Ep/Eacc 2.19 (2.14 inner cell)Bp/Eacc [mT/(MV/m)] 4.79 (4.58 inner cell)R/Q [Ω] 485G [Ω] 233k [%] 1.52QBCS @ 2 K [109] 36.2Frequency [MHz] 805.00Field Flatness [%] 1.1
KL70 = -0.7 [Hz/(MV/m)2] KL80 = -0.8 [Hz/(MV/m)2]
Nb thickness = 3.8 mm
Effective β that matches the TTF curve = 0.830
Geometrical ParametersInner cell End Cell Left End Group (coupler)
Left RightL [mm] 75.5 75.5 75.5Riris [mm] 48.8 48.8 48.8 70.0D [mm] 164.15 164.15 166.11d [mm] 15.0 13.0 15.0 13.0r 1.8 1.6 1.8 1.6R 1.0 1.0 1.0α [deg] 7.0 10.072 7.0 10.0
Tool used also for the SNS cavity design
Longitudinal eigenmode analysis
P. Pierini EPAC 2002, Paris, 3-7 June 2002 15
Conceptual design: linac design
Build linac from simple rules, with control of longitudinal & transverse phase advances
10.0 mm X 3.000 mrad
A= -2.479 B= 8.6115 HA= -0.467 B= 3.0957 V
10.0 Deg X 1000.0 KeV
A= 0.001 B= 0.0476 Z
10.0 mm X 3.000 mrad
10.0 Deg X 1000.0 KeV
10.0 mm 10. Deg Length= 506397.mmVert
Horiz, Long
1
Q
2 3
Q
4 5
TNK
6 7
TNK
8 9
Q
10 11
Q
12 13
TNK
14 15
TNK
16 17
Q
18 19
Q
20 21
TNK
22 23
TNK
24 25
Q
26 27
Q
28 29
TNK
30 31
TNK
32 33
Q
34 35
Q
36 37
TNK
38 39
TNK
40 41
Q
42 43
Q
44 45
TNK
46 47
TNK
48 49
Q
50 51
Q
52 53
TNK
54 55
TNK
56 57
Q
58 59
Q
60 61
TNK
62 63
TNK
64 65
Q
66 67
Q
68 69
TNK
70 71
TNK
72 73
Q
74 75
Q
76 77
TNK
78 79
TNK
80 81
Q
82 83
Q
84 85
TNK
86 87
TNK
88 89
Q
90 91
Q
92 93
TNK
94 95
TNK
96 97
Q
98 99
Q
100101
TNK
102103
TNK
104105
Q
106107
Q
108109
TNK
110111
TNK
112113
Q
114115
Q
116117
TNK
118119
TNK
120121
Q
122123
Q
124125
TNK
126127
TNK
128129
Q
130131
Q
132133
TNK
134135
TNK
136137
Q
138139
Q
140141
TNK
142143
TNK
144145
Q
146147
Q
148149
TNK
150151
TNK
152153
Q
154155
Q
156157
TNK
158159
TNK
160161
Q
162163
Q
164165
TNK
166167
TNK
168169
Q
170171
Q
172173
TNK
174175
TNK
176177
Q
178179
Q
180181
TNK
182183
TNK
184185
Q
186187
Q
188189
TNK
190191
TNK
192193
Q
194195
Q
196197
TNK
198199
TNK
200201
Q
202203
Q
204205
TNK
206207
TNK
208209
Q
210211
Q
212213
TNK
214215
TNK
216217
Q
218219
Q
220221
TNK
222223
TNK
224225
Q
226227
Q
228229
TNK
230231
TNK
232233
Q
234235
Q
236237
TNK
238239
TNK
240241
Q
242243
Q
244245
TNK
246247
TNK
248249
Q
250251
Q
252253
TNK
254255
TNK
256257
Q
258259
Q
260261
TNK
262263
TNK
264265
Q
266267
Q
268269
TNK
270271
TNK
272273
Q
274275
Q
276277
TNK
278279
TNK
280281
Q
282283
Q
284285
TNK
286287
TNK
288289
Q
290291
Q
292293
TNK
294295
TNK
296297
Q
298299
Q
300301
TNK
302303
TNK
304305
Q
306307
Q
308309
TNK
310311
TNK
312313
Q
314315
Q
316317
TNK
318319
TNK
320321
Q
322323
Q
324325
TNK
326327
TNK
328329
Q
330331
Q
332333
TNK
334335
TNK
336337
Q
338339
Q
340341
TNK
342343
TNK
344345
Q
346347
Q
348349
TNK
350351
TNK
352353
Q
354355
Q
356357
TNK
358359
TNK
360361
Q
362363
Q
364365
TNK
366367
TNK
368369
Q
370371
Q
372373
TNK
374375
TNK
376377
Q
378379
Q
380381
TNK
382383
TNK
384385
TNK
386387
TNK
388389
Q
390391
Q
392393
TNK
394395
TNK
396397
TNK
398399
TNK
400401
Q
402403
Q
404405
TNK
406407
TNK
408409
TNK
410411
TNK
412413
Q
414415
Q
416417
TNK
418419
TNK
420421
TNK
422423
TNK
424425
Q
426427
Q
428429
TNK
430431
TNK
432433
TNK
434435
TNK
436437
Q
438439
Q
440441
TNK
442443
TNK
444445
TNK
446447
TNK
448449
Q
450451
Q
452453
TNK
454455
TNK
456457
TNK
458459
TNK
460461
Q
462463
Q
464465
TNK
466467
TNK
468469
TNK
470471
TNK
472473
Q
474475
Q
476477
TNK
478479
TNK
480481
TNK
482483
TNK
484485
Q
486487
Q
488489
TNK
490491
TNK
492493
TNK
494495
TNK
496497
Q
498499
Q
500501
TNK
502503
TNK
504505
TNK
506507
TNK
508509
Q
510511
Q
512513
TNK
514515
TNK
516517
TNK
518519
TNK
520521
Q
522523
Q
524525
TNK
526527
TNK
528529
TNK
530531
TNK
532533
Q
534535
Q
536537
TNK
538539
TNK
540541
TNK
542543
TNK
544545
Q
546547
Q
548549
TNK
550551
TNK
552553
TNK
554555
TNK
556557
Q
558559
Q
560561
TNK
562563
TNK
564565
TNK
566567
TNK
568569
Q
570571
Q
572573
TNK
574575
TNK
576577
TNK
578579
TNK
580581
Q
582583
Q
584585
TNK
586587
TNK
588589
TNK
590591
TNK
592593
Q
594595
Q
596597
TNK
598599
TNK
600601
TNK
602603
TNK
604605
Q
606607
Q
608609
TNK
610611
TNK
612613
TNK
614615
TNK
616617
Q
618619
Q
620621
TNK
622623
TNK
624625
TNK
626627
TNK
628629
Q
630631
Q
632633
TNK
634635
TNK
636637
TNK
638639
TNK
640641
Q
642643
Q
644645
TNK
646647
TNK
648649
TNK
650651
TNK
652653
Q
654655
Q
656657
TNK
658659
TNK
660661
TNK
662663
TNK
664665
Q
666667
Q
668669
TNK
670671
TNK
672673
TNK
674675
TNK
676677
Q
678679
Q
680681
TNK
682683
TNK
684685
TNK
686687
TNK
688689
Q
690691
Q
692693
TNK
694695
TNK
696697
TNK
698699
TNK
700701
Q
702703
Q
704705
TNK
706707
TNK
708709
TNK
710711
TNK
712713
Q
714715
Q
716717
TNK
718719
TNK
720721
TNK
722723
TNK
724725
Q
726727
Q
728729
TNK
730731
TNK
732733
TNK
734735
TNK
736737
Q
738739
Q
740741
TNK
742743
TNK
744745
TNK
746747
TNK
748749
Q
750751
Q
752753
TNK
754755
TNK
756757
TNK
758759
TNK
760761
Q
762763
Q
764765
TNK
766767
TNK
768769
TNK
770771
TNK
772773
Q
774775
Q
776777
TNK
778779
TNK
780781
TNK
782783
TNK
784785
Q
786787
Q
788789
TNK
790791
TNK
792793
TNK
794795
TNK
796
A= -0.957 B= 15.5345 HA= -0.210 B= 10.0358 V
A= -0.122 B= 0.0015 Z
I= 40.00 mAW = 87.000 2007.422 MeVFREQ= 704.40 MHz WL= 425.60 mmEMITI= 4.221 4.221 1000.00EMITO= 0.625 0.625 1000.00
PRINTOUT VALUES NP NE VALUE 1 1 8.2720 1 6 468.0000 2 6 0.0000 3 6 0.0000
MATCHING TYPE = 9DESIRED VALUES (BEAMF) alpha betax -2.0553 15.4239y -0.7381 7.3608z -0.0259 0.0060
MATCH VARIABLES (NC=6) MP ME VALUE 3 373 -31.6848 3 381 -16.8251 1 369 14.2740 1 371 -14.1363 1 377 15.0778 1 379 -14.6226
CODE: TRACE3D vMI1FILE: G:\dynrash\224\cav\cav-quad.t3dDATE: 22/12/1999TIME: 17:56:59
Find matched beam solution in all linac
Poster WEPLE109: Adiabatic Matching in Periodic Accelerating Lattices for Superconducting Proton Linacs
Poster WEPLE109: Adiabatic Matching in Periodic Accelerating Lattices for Superconducting Proton Linacs
Run non-linear multi-particle simulations for confirmation of design
P. Pierini EPAC 2002, Paris, 3-7 June 2002 16
352 MHz cavities with CERN (MOU) Use LEP II sputtering technology Single cell and 5 cell sputtered β = 0.85 Cavity integrated in a LEP type cryostatAll tests reached the design goals, indeed performed as the best LEP batchBut: Bulk niobium is needed at lower β, and the gradient is moderate w.r.t 704 MHz
352 MHz β=0.85 prototypes with CERN
Test in a modified LEPII cryomodule (Aug. 2001)
Powered to 250 kW 7 MV/m
P. Pierini EPAC 2002, Paris, 3-7 June 2002 17
0 20 40 60 80 100 120 140109
1010
1011
Quench No quenchQuench
design value, Bp=50 mT
Ep=30.3 MV/m,
Eacc
=8.5 MV/m
Q0
Bp [mT], E
p [MV/m], E
acc [MV/m]
Z101 RRR=30 Z102 RRR=30 Z103 RRR=250 Z104 RRR=250
0 10 20 30 40 50 60 70
0 2 4 6 8 10 12 14 16 18 20 22
Poster THPDO023: RF Tests of the Single Cell Prototypes for the TRASCO β=0.47 Cavities
Poster THPDO023: RF Tests of the Single Cell Prototypes for the TRASCO β=0.47 Cavities
β=0.47 single cell cavities prototypes
For 1-cell:Ep/Eacc = 2.90Bp/Eacc = 5.38 mT/(MV/m)
For 5-cell:Ep/Eacc = 3.57Bp/Eacc = 5.88 mT/(MV/m)
Max Epeak = 74 MV/mMax Bpeak = 138 mT
Fabricated with RRR>30 & RRR>250 Niobium at ZanonBCP, HPR and tests at TJNAF (Z104) and Saclay (Z101-Z103)
Two 5 cell cavities are under fabrication
Bp
Ep
Eacc
P. Pierini EPAC 2002, Paris, 3-7 June 2002 18
Baseline of the smooth linac design
Continuous phase advances at transitions
RFQ
P. Pierini EPAC 2002, Paris, 3-7 June 2002 19
Full SC linac from 5 MeV to 1 GeV
Results of non-linear simulationsNo particle losses, beams well confined
x rms envelope
y rms envelope
Phase rms envelope
Input @ 5 MeV 105 ptcl
Output @ 1 GeV
P. Pierini EPAC 2002, Paris, 3-7 June 2002 20
Rms emittances growth (from end of RFQ to full energy) < 2%
Avoided: Structure resonances Tune resonances Big tune depression
Guaranteed: Smooth beamline changes Good matching procedures
P. Pierini EPAC 2002, Paris, 3-7 June 2002 21
Rms emittances growth (from end of RFQ to full energy) < 2%
Avoided: Structure resonances Tune resonances Big tune depression
Guaranteed: Smooth beamline changes Good matching procedures
P. Pierini EPAC 2002, Paris, 3-7 June 2002 22
The effort to build a complete ADS system exceeds the capabilities (and the funding availability) of any national program like TRASCO
TRASCO means to provide significant R&D and prototipical effort along the road to the design of a transmuter system
cfr. A European Roadmap for Developing Accelerator Driven Systems (ADS) for Nuclear Waste Incineration, by the European Technical Working Group on ADS, April 2001 (available in http://itumagill.fzk.de/ADS/)
Already in the FP5 of the European Commission a Program has beenfunded: PDS-XADS Preliminary Design Studies for an eXperimental Accelerator Driven System
25 Partners, from Research Institutions to EU Industries 12 M Program (50% supported by the Commission) Several Working Packages, dealing with various aspects of an ADS WP3 is dedicated to the Accelerator
More to come in the FP6
Perspectives