Presentation is loading. Please wait.

Presentation is loading. Please wait.

Carbon Target Design and Optimization for an Intense Muon Source X. Ding, UCLA H.G. Kirk, BNL K.T. McDonald, Princeton Univ. 2014 MAP Winter Collaboration.

Published byLoraine Bruce Modified over 8 years ago

Similar presentations

Presentation on theme: "Carbon Target Design and Optimization for an Intense Muon Source X. Ding, UCLA H.G. Kirk, BNL K.T. McDonald, Princeton Univ. 2014 MAP Winter Collaboration."— Presentation transcript:

1 Carbon Target Design and Optimization for an Intense Muon Source X. Ding, UCLA H.G. Kirk, BNL K.T. McDonald, Princeton Univ. 2014 MAP Winter Collaboration Meeting 3-7 December, 2014 SLAC 112/4/14

2 OUTLINE Carbon target concept and fieldmap ROOT-based geometry setting for target station Carbon target optimization and yield comparison (no beam dumps) Design of beam dumps Summary 12/4/142

3 Carbon Target Concept 12/4/143 http://physics.princeton.edu/mumu/target/hptw5_poster.pdf

4 Fieldmap along SC axis (Capture Magnet 20to2T5m120cm) 12/4/144

5 ROOT-based Target Setting 12/4/145 New target setting (ROOT-based geometry). Previous target setting (non-standard and standard geometry in MARS15)

6 Carbon Target Optimization Simulation code: MARS15(2014) with ICEM 4 = 1 (default) and ENRG 1 = 6.75, 2 = 0.02, 3 = 0.3, 4 = 0.01, 5 = 0.05, 6 = 0.01, 7 = 0.01 ; Carbon target configuration: Fieldmap (20T  2T) with taper length of 5 m, Graphite density = 1.8 g/cm 3 ; Beam pipe radius: 13 cm (initial) and 23 cm (final); Proton beam: 6.75 GeV (KE), 1 MW, ¼ of target radius, waist and 5-50 μm geometric emittance at z = 0 m (intersection point), launched at z = -100 cm; Production collection: z = 50 m, 40 MeV < KE < 180 MeV; Particle distribution for front end: created at z = 2 m. 12/4/146

7 New Procedure for Generating the Launched Beam at z = -100 cm Generate a negative proton beam having desired 2D emittance and waist at z = 0; Track back all negative protons in the beam from z = 0 to the left side and collect them at z = -100 cm; Generating a positive proton beam by changing the signs of charge and px, py and pz of negative proton beam above. This will be the launched beam to the right side at z = -100 cm. 12/4/147

8 Yield Comparison (5 μm emittance) (no-tilt vs. tilt proton beam, no beam dump) 12/4/148 Optimized target length is 80 cm and target radius is 0.8 cm for tilt or 0.64 cm for no-tilt beam. Optimized tilt beam angle is 65 mrad. Collinear target and beam. TR/BR (target radius/beam radius) = 4. ~ 13% advantage to tilting the beam/target

9 Yield Comparison (varied emittance) (no-tilt vs. tilt proton beam, no beam dump) 12/4/149 ~ 13% advantage to tilting the beam/target; For r target = 8 mm, same yield for any emittance  20  m; Little loss of muon yield for 20  m emittance; Yield for 50  m emittance and target radius of 1.2 cm is only 10% less than that for the nominal case of 5  m emittance and 0.8 cm target radius; We prefer target radius  8 mm (beam radius  2 mm) for viable radiation cooling of the target. http://physics.princeton.edu/mumu/target/targettrans106.pdf

10 Advantage of Higher Emittance Beams 8/8/1410 For a fixed target radius (8 mm on this page), higher beam emittance  higher beam divergence, more diffuse beam at upstream end of target,  lower peak power deposition. For emittance  20  m the peak power deposition is only  1/2 that for 5  m,  additional advantage to use of higher emittance beams. http://physics.princeton.edu/mumu/target/Ding/ding_140807.pdf Simulation with MARS15 by N. Souchlas Result confirmed by J. Back with FLUKA

11 Simple Setup of Beam Dumps in ROOT (same tilt angle as the target ) 12/4/1411 Target: length of 80 cm (z = -40 cm to z = 40 cm), radius of 0.80 cm, beam angle of 65 mrad, co-linear target and beam, TR/BR = 4 1 st beam dump rod: length of 60 cm (z = 40 cm to z = 100 cm), Radius 3 x target radius, beam angle of 65 mrad 2 nd beam dump rod: length of 60 cm (z = 100 cm to z = 160 cm), Radius 3 x target radius, beam angle of 65 mrad

12 Advanced Setup of Beam Dumps in ROOT Rotation defined by GRANT3 angles: TGeoRotation *r1 = new TGeoRotation(); r1->SetAngles(th1,phi1, th2,phi2, th3,phi3) This is a rotation defined in GEANT3 style. Theta and phi are the spherical angles of each axis of the rotated coordinate system with respect to the initial one. 12/4/1412

13 Advanced Setup of Beam Dumps in ROOT Rotated cylinder can be described as having axes 1, 2 and 3, where 3 is the symmetry axis and goes from the origin to the specified point (x,y,z). Axis 1 is defined to lie in the x-z plane phi1 = 0 th1 = acos(x / sqrt(x^2 + z^2)) phi2 = atan2[(x^2 + z^2)/x, –y] th2 = acos[- y z /sqrt(L^2 (x^2 + z^2) ] th3 = acos(z/L) phi3 = atan2(y,x) 12/4/1413

14 Advanced Setup of Beam Dumps in ROOT 12/4/1414 X = 0 cm X = -4 cm

15 Advanced Setup of Beam Dumps in ROOT 12/4/1415 Target: length of 80 cm (z = -40 cm to z = 40 cm) and radius: 0.80 cm, beam angle of 65 mrad in the y-z plane, center of end of target (0,-2.6,40) 1 st beam dump rod: radius 3 x target radius, length of 60 cm (z = 40 cm to z = 100 cm), centers of end faces: (0,-2.6,40), (-2.3,-5.9,100) 2 nd beam dump rod: radius 3 x target radius, length of 60 cm (z = 100 cm to z = 160 cm), centers of end faces: (-2.3,-5.9,100), (-5.0,-8.6,160) End of target End of 1 st dump End of 2 nd dump

16 Particles at z = 5 m from Carbon Target 1 MW beam (9.26×10 14 protons with KE of 6.75 GeV) beam angle = 65 mrad, target radius = 0.8 cm L dump (cm) R dump /R ta rget Total KE (protons) (r <23 cm) [Watts] Total KE (non-protons) [Watts] Protons KE > 6 GeV (×9.26×10 10 ) Yield at z = 50 m (×9.26×10 10 ) Geometry Setting of Beam Dumps in MARS 00883591054543011240.7 120366430949361301134.6 Advanced ROOT-based Geometry Setting for Beam Dumps 0084479983132831211 120364199849661161061 Simple ROOT-based Target Geometry Setting for Beam Dumps (same tilt as the target) 120363415855141361096 12/4/1416

17 Summary Target System: 1 MW, 6.75 GeV (KE) proton beam, the 20 T field on target drops to the ~2 T field in the rest of the Front End over ~ 5 m) and graphite target. Optima for graphite target (tilt beam): length = 80 cm, radius = 8 mm (with 2 mm rms beam radius), tilt angle = 65 mrad. Successfully designing the target system and complicated beam dumps with ROOT-based geometry. For 6.75 GeV (KE) beam, about 13% higher production by tilting the carbon target/proton beam. 12/4/1417

18 Summary (Cont’d) Higher beam emittance and higher target radius are favored: – Improved the radiation cooling of the target, – Lower peak power deposition, – Only slight decrease in the particle yield, – Easier for Proton Driver to deliver higher emittance. Graphite proton beam dump now setup via ROOT: – 120 cm long, 24 mm radius, 2 segments, – Intercepts most of the (diverging) unscattered proton beam. Particle distributions were generated at z = 2m for Front End studies. 12/4/1418

Download ppt "Carbon Target Design and Optimization for an Intense Muon Source X. Ding, UCLA H.G. Kirk, BNL K.T. McDonald, Princeton Univ. 2014 MAP Winter Collaboration."

Similar presentations

Comparison of Particle Production between MARS and FLUKA (Update) X. Ding, UCLA Target Studies Aug. 8, 2013 18/8/13.

Comparison of Particle Production between MARS and FLUKA (Update) X. Ding, UCLA Target Studies Aug. 8, /8/13.
SUPERCONDUCTING SOLENOIDS - SHIELDING STUDIES 1. N. Souchlas BNL (Oct. 5, 2010)

SUPERCONDUCTING SOLENOIDS - SHIELDING STUDIES 1. N. Souchlas BNL (Oct. 5, 2010)
KT McDonald Target Studies Weekly Meeting July 10, 2014 1 Power Deposition in Graphite Targets of Various Radii K.T. McDonald, J. Back, N. Souchlas July.

KT McDonald Target Studies Weekly Meeting July 10, Power Deposition in Graphite Targets of Various Radii K.T. McDonald, J. Back, N. Souchlas July.
Magnetic Configuration of the Muon Collider/ Neutrino Factory Target System Hisham Kamal Sayed, *1 H.G Kirk, 1 K.T. McDonald 2 1 Brookhaven National Laboratory,

Magnetic Configuration of the Muon Collider/ Neutrino Factory Target System Hisham Kamal Sayed, *1 H.G Kirk, 1 K.T. McDonald 2 1 Brookhaven National Laboratory,
POSTER TEMPLATE BY: www.Poster Presentations.com POSTER TEMPLATE BY: www.Poster Presentations.com Outlet Inlet n’=375 n=150 n φ =75 (dφ=1.2 ⁰ ) Extra Terms.

POSTER TEMPLATE BY: Presentations.com POSTER TEMPLATE BY: Presentations.com Outlet Inlet n’=375 n=150 n φ =75 (dφ=1.2 ⁰ ) Extra Terms.
Harold G. Kirk Brookhaven National Laboratory Solenoid Focus of Pions for Superbeams NUFACT06 Irvine, Ca. August 28, 2006.

Harold G. Kirk Brookhaven National Laboratory Solenoid Focus of Pions for Superbeams NUFACT06 Irvine, Ca. August 28, 2006.
Meson Production at 8 GeV for IDS120h X. Ding, UCLA Target Studies, Dec. 27, 2011.

Meson Production at 8 GeV for IDS120h X. Ding, UCLA Target Studies, Dec. 27, 2011.
Meson Production Comparison between Hg and Ga at 8 GeV X. Ding, UCLA Target Studies, Oct. 04, 2011.

Meson Production Comparison between Hg and Ga at 8 GeV X. Ding, UCLA Target Studies, Oct. 04, 2011.
Meson Production Comparison between HG and GA at 8 GeV (Update) X. Ding, UCLA Target Studies, Oct. 18, 2011.

Meson Production Comparison between HG and GA at 8 GeV (Update) X. Ding, UCLA Target Studies, Oct. 18, 2011.
Particle Production of a Carbon/Mercury Target System for the Intensity Frontier X. Ding, UCLA H.G. Kirk, BNL K.T. McDonald, Princeton Univ. 2015 MAP Spring.

Particle Production of a Carbon/Mercury Target System for the Intensity Frontier X. Ding, UCLA H.G. Kirk, BNL K.T. McDonald, Princeton Univ MAP Spring.
Operated by Brookhaven Science Associates for the U.S. Department of Energy A Pion Production and Capture System for a 4 MW Target Station X. Ding, D.

Operated by Brookhaven Science Associates for the U.S. Department of Energy A Pion Production and Capture System for a 4 MW Target Station X. Ding, D.
Pion capture and transport system for PRISM M. Yoshida Osaka Univ. 2005/8/28 NuFACT06 at UCI.

Pion capture and transport system for PRISM M. Yoshida Osaka Univ. 2005/8/28 NuFACT06 at UCI.
Energy Deposition of 4-MW Beam Power in a Mercury Jet Target Xiaoping Ding UCLA Target Studies Meeting, Feb. 9, 2010.

Energy Deposition of 4-MW Beam Power in a Mercury Jet Target Xiaoping Ding UCLA Target Studies Meeting, Feb. 9, 2010.
Harold G. Kirk Brookhaven National Laboratory Meson Production Efficiencies IDS Target Meeting CERN December 17, 2008.

Harold G. Kirk Brookhaven National Laboratory Meson Production Efficiencies IDS Target Meeting CERN December 17, 2008.
1 Meson Production Simulations X. Ding, D. B. Cline UCLA H. Kirk, J. S. Berg BNL N u F a c t 0 9 11th International Workshop on Neutrino Factories, Superbeams.

1 Meson Production Simulations X. Ding, D. B. Cline UCLA H. Kirk, J. S. Berg BNL N u F a c t th International Workshop on Neutrino Factories, Superbeams.
Above: Energy deposition in the superconducting magnet and the tungsten-carbide shield inside them. Approximately 2.4 MW must be dissipated in the shield.

Above: Energy deposition in the superconducting magnet and the tungsten-carbide shield inside them. Approximately 2.4 MW must be dissipated in the shield.
Optimization of Target Parameters for a Tungsten Target (Half Density) at 8GeV X. Ding Target Studies Nov. 2, 2010.

Optimization of Target Parameters for a Tungsten Target (Half Density) at 8GeV X. Ding Target Studies Nov. 2, 2010.
Energy Deposition of 4MW Beam Power in a Mercury Jet Target Xiaoping Ding UCLA Target Studies Mar. 9, 2010 (Update of talk on Feb. 9, 2010)

Energy Deposition of 4MW Beam Power in a Mercury Jet Target Xiaoping Ding UCLA Target Studies Mar. 9, 2010 (Update of talk on Feb. 9, 2010)
Harold G. Kirk Brookhaven National Laboratory Target System Update IDS-NF Plenary Meeting Arlington, VA October 18, 2011.

Harold G. Kirk Brookhaven National Laboratory Target System Update IDS-NF Plenary Meeting Arlington, VA October 18, 2011.
1 Muon Yield Comparisons for Different ICOOL Versions and Lattices X. Ding Front End, Nov. 23, 2010.

1 Muon Yield Comparisons for Different ICOOL Versions and Lattices X. Ding Front End, Nov. 23, 2010.

Similar presentations

Ads by Google