Beam instrumentation at the 1-MW proton J-PARC RCS

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Beam instrumentation at the 1-MW proton J-PARC RCS HB2014 54th ICFA Advanced Beam Dynamics Workshop on High-Intensity, High-Brightness and High Power Hadron Beams East Lansing, MI Nov.12, 2014 Kazami Yamamoto for 3GeV RCS Group 2014/11/12 HB2014 1

Contents Introduction Regular monitors for beam commissioning BPM Exciter & Tune BPM CT BLM IPM WSM/MWPM/MRPM New monitors for further safety/quality of beam Monitors for safety/stable operation Fast interlock by CT and profile check on target redundant MPS by BLM Injection halo monitors VWM L3BT Scrapers & BLM, CT Extraction Halo monitors WSM & BLM OTR monitor Delayed proton monitor for Mu-e conversion measurement 2014/11/12 HB2014 2

Introduction J-PARC RCS Parameters and Monitors 2014/11/12 HB2014 3

Regular monitors for beam commissioning BPM Exciter & Tune BPM CT BLM IPM MWPM N. Hayashi et. al., BEAM INSTRUMENTATIONS FOR THE J-PARC RCS COMMISSIONING, Proc. EPAC2008, TUPC034 2014/11/12 HB2014 4

Beam Position Monitor(BPM) Inner diameter of the BPM detectors is larger than 250 mm -> Diagonal cut was chosen to ensure linear response Diagonal cut BPM system can record the full 25 Hz pulse data for the so-called COD mode (averaged beam position is stored). it can also store the whole waveform data for further analysis, like turn- by-turn position calculation(not 25Hz but 1 shot per several seconds). The position accuracy is estimated to be about 0.5 mm using a newly developed Beam Based Alignment method. N. Hayashi et. al., Beam position monitor system of J-PARC RCS, NIM A, Volume 677, p. 94-106 2014/11/12 HB2014 5

Tune Tune measurement 185mm 586mm Small loss appeared here due to the stopband of n=6.5. (A) Adjusted! (B) (B) Horizontal Vertical (A) Exciter AMP Freq:100 khz-7 MHz Power:1 kw Measurement Calculation 2014/11/12 HB2014 6 Time (ms)

Current Transformer(CT) Dump line FCT :limit beam current to dump V 2 /V 1 =80% f 2 =-100 to 0 deg Dp/p=-0.1%(left), -0.2%(right) Longitudinal profile by WCM 1 st DCCT:purchased from Bergoz (BDCCT-S-380-H) 2 nd DCCT:made by the FINMET(FT3M) Range:150mA-15A Bandwidth:DC-20kHz Inner Diameter:380mm 2 nd DCCT Coil:1000turn Fast CT:made by the FINMET(FT3M) Coil:20turn Bandwidth:2kHz-10MHz WCM:Shunt impedance: 0.1 ohm(10 ohm*100 para) Measurements (WCM) Numerical simulations 2014/11/12 HB2014 7

Beam Loss Monitor Proportional counter(pblm) Scintillation counter(sblm) SBLM signal comparison Simulations PBLM put around the RCS:MPS Loss at collimators Loss at arc and extraction (sensitivities are too high) Reflection from Ext. Dump Reflection from H0 Dump Experimental data from SBLM Injection Extraction Arc Arc RF Arc Injection Arc The time structure and the amount of the beam loss are well in agreement with the simulation. 2014/11/12 HB2014 Integrations of PBLM signal are archived at all times. PBLM signals are also compared with the limit value at every shot. 8

Residual dose after 5-month 300kW user operation (2-day cooling and 2-month cooling) BLM-MPS kept accelerator less activation. 2014/11/12 HB2014 9

Ionization Profile Monitor(IPM) Prototype:electric field was distorted Improves the electorode shapes and registers 3 IPM installed 2:Dispersive Arc 1:Ext-straight (Dispersion free) New:electric field becomes uniform Results of injection beam orbit correction H. Harada et. al., UPGRADE OF IONIZATION PROFILE MONITOR (IPM) IN THE J-PARC 3-GeV RCS, Proc. IPAC2012, MOPPR029 2014/11/12 HB2014 10

Wire Scan Monitor(WSM) /Multi Wire Profile Monitor(MWPM) /Multi Ribbon Profile Monitor(MRPM) Used at beam transport lines or one-pass operation (L3BT, 3-50BT or injection line correction) MWPM7 (installed in the injection dump line) is used not only to measure the profile, but to measure the amount of H 0 and H - unstripped particles MWPM at RCS injection point MRPM at 3-50 BT P. K. Saha et. al., Quantitative monitoring of the stripper foil Y. Hashimoto et. al., MULTI-RIBBON PROFILE MONITOR USING degradation in the 3-GeV rapid cycling synchrotron of the Japan CARBON 2014/11/12 GRAPHITE FOIL FOR J-PARC, Proc. HB2010, WEO2A01 HB2014proton accelerator research complex, J. Radioanal. Nucl. Chem. 11 299, 2, 1041-1046 (2014)

New monitors for further safety/quality of beam Monitors for safety/stable operation Fast interlock by CT and profile check on target Injection halo monitors VWM L3BT Scrapers & BLM, CT Extraction Halo monitors WSM&BLM OTR monitor Delayed proton monitor for m-e conversion measurement 2014/11/12 HB2014 12

Monitors for safety/stable operation The radiation leak accident was happened in the hadron experimental hall at J- PARC on May 23, 2013. The accident was caused by a target sublimation due to an abnormal beam extraction from the main ring. To detect and prevent the radiation leakage, we improved the monitoring systems and interlocks. Monitoring of the beam profile on the mercury target New interlock system that can stop the beam immediately when the beam current exceed the limit. <10 msec 2014/11/12 HB2014 13

Injection beam halo monitor(1) Vibration Wire Monitor (VWM) beam on beam off f = 53.13Hz T = 8.34 [K] purchased from Bergoz (sus316l, φ0.1mm wire) 1950 1940 1930 We tested VWM to measure injection beam profile. But, we cannot take data at some frequencies. Perhaps electric circuit has some problem. 1870 21:53:17 21:56:10 21:59:02 22:01:55 22:04:48 22:07:41 K. Okabe et. al., Feasibility Studies of a Vibration Wire Monitor and a Halo Scraper in the J-PARC L3BT, Journal of the Korean Physical Society, 2014/11/12 Vol. 63, No. 7, October 2013, pp. 1379 1384 HB2014 14 1920 1910 1900 1890 1880

Injection beam halo monitor(2) L3BT Scrapers & BLM, CT Dump for Scraped halo Scraped H + Beam core H - The amount of the scraped halo (H-) was measured by the scintillation detector and the CT at dump line. This system has two advantages of 1) redundant monitors by another principles 2) absolute value measurement by CT Measured results are consistent, and the scintillation detector and the CT are able to detect less than 1E-4 halo. 2014/11/12 8 Scrapers K. Okabe et. al., Feasibility Studies of a Vibration Wire Monitor and a Halo Scraper in the J-PARC L3BT, Journal of the Korean Physical Society, Vol. 63, No. 7, October 2013, pp. 1379 1384 HB2014 15

Extraction beam halo monitor(1) WSM & BLM New beam halo monitor is combined a wire type beam scraper and some beam loss monitors. To use the beam loss monitors with different sensitivities, it has wide dynamic range. Beam profile including both of the beam core and halo can be measured. Some kinds of beam loss monitors radiation Extraction beam Vertical scanning device wire scanner Horizontal scanning device LS-BLM integral [mv*sec] 0.0-0.2-0.4-0.6-0.8 Vertical wire scanner Beam loss radiation Two bunched extraction beam Raw data macro = 500ms CH1: LS-BLM_m3 CH2: LS-BLM (1) CH3: LS-BLM (2) P-BLM (Proportional chamber type ) AIC-BLM (Air iron chamber) S-BLM ( Schintillatorphotomultiplier ) M. Yoshimto, et. al., Beam halo measurement using a -1.0 combination of a wire scanner type beam scraper and some 2014/11/12 HB2014 10 7 16 290 300 310 320 330 340 350 290 300 310 320 330 340 beam loss monitors in J-PARC 3-GeV RCS., HB2014, MOPAB44 Vertical position [mm] number of perticle 10 13 10 12 10 11 10 10 10 9 10 8 After correction macro = 500ms LS-BLM_m3 LS-BLM (1) LS-BLM (2) fit_ls-blm_m3: center = 323.62[mm] / =10.534[mm] fit_ls-blm (2) center = 323.4[mm] / =10.41[mm] Y scan [mm] 350

Extraction beam halo monitor(2) Optical Transition Radiation monitor (OTR) multi-screen system 2014/11/12 Y. Hashimoto et. al., Two-dimensional and Wide Dynamic Range Profile Monitor Using OTR/Fluorescence Screens for Diagnosing Beam Halo of Intense Proton Beams, HB2014, TU02AB HB2014 17

Delayed proton monitor for m-e conversion measurement DeeMe=Direct electron emission measurement for Mu- e conversion 300nsec ~ 1 msec Measurment time window ->Required rate of delayed proton : < 10-18 ->Correspond to less than few protons within 1 hour = 9*10 4 shot(rep. = 25Hz) (1 pulse ~ 1*10 14 protons) ->It is impossible to measure such slight protons by ordinary monitors K. Yamamoto et. al., Measurement system of the background proton in DeeMe experiment at J-PARC, Proc. 2 nd International Symposium on Science at J-PARC (2014) 2014/11/12 HB2014 Beam background when BG proton exists 10 18

Delayed proton monitor for m-e conversion measurement Estimation of scattered proton trajectory by G4BeamLine -> Assume 324~5000p mm-mrad. emittance uniform beam Ratio of the number of the proton that hit the outside scintillators to the number of the proton that pass through the 3NBT line N[scintillator hit]/n[pass through 3NBT]=ε=0.025 Measurement: Mar. 7, 2013 May 25, 2013 Total coincident count in the time window:87 Total extracted protons: 3.13*10 21 R delayed p =1.1*10-18 K. Yamamoto et. al., Measurement system of the background proton in DeeMe experiment at J-PARC, Proc. 2 nd International Symposium on 2014/11/12 HB2014 19 Science at J-PARC (2014)

Summary We achieved 770kW output power. Since regular monitors worked well, so far we understand the characteristics of the beam. To establish further stable and safety operation, some monitors and interlocks are improved To reduce the beam loss, high sensitive halo monitors are developed. 2014/11/12 HB2014 20

2014/11/12 HB2014 21

Beam Loss Monitor SBLM signal comparison Simulations PBLM signals around the RCS Loss at collimators Loss at arc and extraction (sensitivities are too high) Reflection from Ext. Dump Reflection from H0 Dump Experiments data from SBLM Injection Extraction Arc Arc RF Arc Injection Arc The time structure and the amount of the beam loss are well in agreement with the simulation. 2014/11/12 HB2014 Integrations of PBLM signal are archived at all times. PBLM signals are also compared with the limit value at every shot. 22

Monitors for safety/stable operation (2) redundant MPS by BLM CH1: CHOP2 RF CH2: CHOP1 RF CH3: RCS BLM MPS 2014/11/12 HB2014 23