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Meson Productions for Target System with GA/HG Jet and IDS120h Configuration X. Ding (Presenter), D. Cline, UCLA H. Kirk, J.S. Berg, BNL Muon Accelerator.

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Presentation on theme: "Meson Productions for Target System with GA/HG Jet and IDS120h Configuration X. Ding (Presenter), D. Cline, UCLA H. Kirk, J.S. Berg, BNL Muon Accelerator."— Presentation transcript:

1 Meson Productions for Target System with GA/HG Jet and IDS120h Configuration X. Ding (Presenter), D. Cline, UCLA H. Kirk, J.S. Berg, BNL Muon Accelerator Program Collaboration Meeting SLAC, March 5, 2012 1

2 Outline Motivation of optimization of GA target Introduction of IDS120h Configuration (Target/Collection system, fieldmap and target geometry) Optimization methods Optimized target parameters and meson productions at proton KE of 8 GeV Optimized target parameters and meson productions at different proton KE (Comparison between HG/GA Jet, between IDS120h/Study2a with HG jet) Focused Incident Proton Beam Summary 2

3 Motivation to Optimize GA Target (Possible target alternative of HG) 3 Pion/muon yields for different atomic Z’s and beam energies (J. Back/X. Ding); Advantages of Gallium: relative efficient meson production (near the NI Peak), liquid state at relatively low temperature ( Melting Point = 29.8 0 C ) and potential for easier handling (H. Kirk). Study 2 NF geometry and B-map Acceptance probability histogram used at z=6m (based on ICOOL)

4 Target/Collection System of IDS120h 4 Count all the pions and muons that cross the transverse plane at z=50m. For this analysis we select all pions and muons with 40 < KE < 180 MeV.

5 Axis Field (Bz at r=0) with IDS120h 5

6 HG/GA Target Geometry (New Setting Procedure) The mercury jet target geometry. The proton beam and mercury jet cross at z=-37.5 cm. 1.Put beam exactly below the HG/GA jet at z=-37.5 cm (see above y-z plot), fix beam/jet intersection point at (0, 0, -37.5 cm) and project beam back to z=-200cm. (Difference: In previous simulation for study 2a, beam launching point is at z=-75 cm.) 2.Initial target parameters at proton KE of 8 GeV: target radius of 5 mm, beam angle of 67 mrad at z=-37.5 cm, beam/jet crossing angle of 33 mrad at z=-37.5 cm. 3.The SC coils, resistive Cu and Shielding are deleted in MARS code for speeding up simulation (Difference: not so in simulation for study2a). 6

7 Optimization Method Take 3 runs in each cycle: 1) Vary jet radius with initial beam angle and beam/jet crossing angle; 2) Vary beam/jet crossing angle with new target radius while keeping jet fixed - always project beam back to z=-200 cm; 3) Vary jet angle with new target radius and beam/jet crossing angle-always keep crossing angle constant- both jet and beam must be rotated about intersection point together and always project beam back to z=- 200 cm. Repeat above cycle until convergence. 7

8 Optimized Target Parameters at 8 GeV at z = -37.5 cm HG GA Target radius, mm Crossing angle, mrad Beam angle, mrad Target radius, mm Crossing angle, mrad Beam angle, mrad Initial(5mm, 33mrad, 67mrad) 1 st Cycle4.6231206.721112 2 nd Cycle4.15231175.51794 3 rd Cycle4.1521.61204.913.292 4 th Cycle4.0420.61174.51390 5 th Cycle4.412.886 6 th Cycle4.41388 8 Nuclear interaction length: HG/14.58 cm, GA/23.92 cm.

9 Meson Productions at 8 GeV (400,000 events) HGGA[N(GA)-N(HG)]/N(HG) Before optimization (Target radius/beam angle/crossing angle) 108528 (5mm/67mrad/33m rad, Initial) 96586 (5mm/67mrad/33 mrad, Initial) -11% (w/t opt) After optimization (Target radius/beam angle/crossing angle) 131362 (4.04mm/117mrad/ 20.6mrad, end of 4 th Cycle) 114401 (4.5mm/90mrad/ 13mrad, end of 4 th Cycle) -12.9% (opt) [N(opt)-N(w/t opt)]/N(w/t opt) +21%+18.4% 9

10 Meson Productions Vs. Run No. at 8 GeV (Number of runs: 0-Initial, 1,4,7,10,13,16-optimized target radius, 2,5,8,11,14,17- optimized crossing angle, 3,6,9,12,15,18-optimized beam angle ) 10

11 Target Radius vs. KE (HG/GA Jet) 11

12 Target Radius vs. KE (IDS120h/Study2a, HG Jet) 12

13 Beam/Jet Crossing Angle vs. KE (HG/GA Jet) 13

14 Beam Angle vs. KE (HG/GA Jet) 14

15 Meson Production vs. KE (HG/GA Jet) 15

16 Meson Production vs. KE (IDS120h/Study2a, HG Jet) 16

17 Focused Incident Proton Beam at 8 GeV 17

18 Focused Incident Proton Beam at 8 GeV (Cont’d) Non-Linear Fit Y=N/(1+K2/beta -2 ) N=1.018 Sqrt(K2)=0.1368 Proton beam emittance is 4.8 μm with beam radius of 0.12 cm and β* of 0.3 m. 18

19 Summary 8 GeV optimized parameters: – Hg r=4.04 mm; beam/jet crossing angle=20.6 mrad ; beam angle = 117 mrad. – Ga r= 4.4 mm; beam/jet crossing angle = 13 mrad; beam angle of 88 mrad. 8GeV meson production for Ga is 12.9% less than for Hg. 19

20 Summary (Cont’d) Ga production peaks near KE = 5 GeV and is comparable to Hg at that KE. For Hg, meson production is reduced by 15% for a proton beam emittance of 5 μm compared to a 0 μm emittance beam. 20

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