Presentation is loading. Please wait.

Presentation is loading. Please wait.

Geant Simulation of Muon Cooling Rings

Published byJunior Townsend Modified over 5 years ago

Similar presentations

Presentation on theme: "Geant Simulation of Muon Cooling Rings"— Presentation transcript:

1 Geant Simulation of Muon Cooling Rings
Amit Klier University of California Riverside

2 A. Klier - Geant simulation
Outline A short reminder from Nufact03 The RFOFO ring Geometry Software improvements Simulation results The small dipole ring Some Results June A. Klier - Geant simulation

3 A. Klier - Geant simulation
Muc_Geant Modified, data-driven Geant3 application for simulating muon cooling Electric fields added Runge-Kutta changed to include changing electric fields (eg RF cavities) Realistic magnetic fields can be read from external field maps June A. Klier - Geant simulation

4 From Nuact03 Tetra ring simulated Rajendran Raja – Nufact 03
June A. Klier - Geant simulation

5 A. Klier - Geant simulation
The RFOFO ring A few code changes w.r.t. Tetra Realistic magnetic field maps read-in (R. Godang, S. Bracker – MC-Note 271) June A. Klier - Geant simulation

6 A. Klier - Geant simulation
The RFOFO ring Full Geant simulation: A. Klier – MC-Note 298 June A. Klier - Geant simulation

7 A. Klier - Geant simulation
The ring geometry 33 m circumference 12 cells (2.75m): A wedge absorber opening angle 110°, pointing ’upwards’ 6 RF cavities 28.75 cm long, iris radius 25 cm flat E field in z direction 2 tilted solenoids inner/outer r = 77/88 cm tilt angle ±3° Only for display here June A. Klier - Geant simulation

8 Closed orbits in a single cell
Solid line – the reference orbit 200 MeV 270 MeV 227 MeV 250 MeV 227 MeV 250 MeV E = 200 MeV E = 270 MeV June A. Klier - Geant simulation

9 Software improvements
ICOOL input/output format used, ecalc9 can be used to calculate emittance Use initial time of particle at entry Use virtual detectors June A. Klier - Geant simulation

10 A. Klier - Geant simulation
Cooling of a muon beam June A. Klier - Geant simulation

11 A. Klier - Geant simulation
Comparison with ICOOL Transmission 6-D emittance June A. Klier - Geant simulation

12 A. Klier - Geant simulation
More comparisons Results after 10 turns: Merit factor Trans. W/O decay With decay Merit Factor Balbekov (MC-264) 70% 56% 55 ICOOL (Fernow) -- 58% 66 Geant 72% 57% 70 June A. Klier - Geant simulation

13 Change beam entry angle
June A. Klier - Geant simulation

14 A. Klier - Geant simulation
The small dipole ring “Weak” (edge) focusing (ideally) scaling Filled with ~10 Atm. hydrogen 77K Dipole field ~ 2 T For P~200 MeV/c, the radius should be ~60 cm June A. Klier - Geant simulation

15 A. Klier - Geant simulation
Field map (from S. Kahn) By in a single quadrant By at R=60 cm Return yoke June A. Klier - Geant simulation

16 A. Klier - Geant simulation
Reference orbit Scale B down to 90% closed orbit: P= MeV/c Rmin=56.32 cm (x=0 in virtual detectors) Rmin Virtual detector plane RF cavity (active region) June A. Klier - Geant simulation

17 A. Klier - Geant simulation
Ellipses Stable up to y~13 cm Y plane symmetry imposed June A. Klier - Geant simulation

18 A. Klier - Geant simulation
Acceptance of the ring “A blob” Py=~19 MeV/c y=~8.5 cm Px=~34 MeV/c More “natural” decrease with no x-z plane symmetry x=~6.5 cm June A. Klier - Geant simulation

19 “Cooling” with no scattering
Xinitial=6 cm Yinitial=8 cm tinitial= –1.5 ns Xcentral=0.04 cm Ycentral=0 cm tcentral=0 ns PXinitial=30 MeV/c PYinitial=17.5 MeV/c Einitial=213 MeV PXcentral=0.12 MeV/c PYcentral=0 MeV/c Ecentral=201.8 MeV June A. Klier - Geant simulation

20 Software improvements
More flexibility – less “hard-coding”, more external parameters Field map reading code used to be RFOFO-specific, now more general More RF parameters Cavities in small dipole ring are off-center So far, only perfect pillbox (or flat field..) cavity are simulated Flexibility: different frequencies, gradients, types can be used in the same channel June A. Klier - Geant simulation

21 A. Klier - Geant simulation
To do Simulate the small dipole ring with a beam Introduce more realistic features: Injection Detectors June A. Klier - Geant simulation

22 A. Klier - Geant simulation
June A. Klier - Geant simulation

23 A. Klier - Geant simulation
Additional Slides June A. Klier - Geant simulation

24 A. Klier - Geant simulation
Comparison with ICOOL Transverse emittance Longitudinal emittance June A. Klier - Geant simulation

Download ppt "Geant Simulation of Muon Cooling Rings"

Similar presentations

PID Detector Size & Acceptance Chris Rogers Analysis PC 04-05-06.

PID Detector Size & Acceptance Chris Rogers Analysis PC
FODO-based Quadrupole Cooling Channel M. Berz, D. Errede, C. Johnstone, K. Makino, Dave Neuffer, Andy Van Ginneken.

FODO-based Quadrupole Cooling Channel M. Berz, D. Errede, C. Johnstone, K. Makino, Dave Neuffer, Andy Van Ginneken.
Bunched-Beam Phase Rotation- Variation and 0ptimization David Neuffer, A. Poklonskiy Fermilab.

Bunched-Beam Phase Rotation- Variation and 0ptimization David Neuffer, A. Poklonskiy Fermilab.
V.Daniel Elvira Status Report on Cooling Simulations using GEANT4 Motivation: Explore a realistic design of a 44/88 MHz based cooling channel for a -factory.

V.Daniel Elvira Status Report on Cooling Simulations using GEANT4 Motivation: Explore a realistic design of a 44/88 MHz based cooling channel for a -factory.
1 Downstream scraping and detector sizes Rikard Sandström University of Geneva MICE collaboration meeting 2007-02-24 CERN.

1 Downstream scraping and detector sizes Rikard Sandström University of Geneva MICE collaboration meeting CERN.
Μ-Capture, Energy Rotation, Cooling and High-pressure Cavities David Neuffer Fermilab.

Μ-Capture, Energy Rotation, Cooling and High-pressure Cavities David Neuffer Fermilab.
PID Detector Size & Acceptance Chris Rogers Analysis PC 04-05-06.

PID Detector Size & Acceptance Chris Rogers Analysis PC
Kirk McDonald Monday, 28th May 2001 1 Report of the International Working Group on Muon Beamlines Bruno Autin, Roberto Cappi, Rob Edgecock, Kirk McDonald,

Kirk McDonald Monday, 28th May Report of the International Working Group on Muon Beamlines Bruno Autin, Roberto Cappi, Rob Edgecock, Kirk McDonald,
V.Daniel Elvira Status Report on Cooling Simulations using GEANT4 Motivation: Explore a realistic design of a 44/88 MHz based cooling channel for a -factory.

V.Daniel Elvira Status Report on Cooling Simulations using GEANT4 Motivation: Explore a realistic design of a 44/88 MHz based cooling channel for a -factory.
Chris Rogers, MICE CM16 Wednesday Plenary Progress in Cooling Channel Simulation.

Chris Rogers, MICE CM16 Wednesday Plenary Progress in Cooling Channel Simulation.
Beamline-to-MICE Matching Ulisse Bravar University of Oxford 2 August 2004 MICE performance with ideal Gaussian beam JUNE04 beam from ISIS beamline (Kevin.

Beamline-to-MICE Matching Ulisse Bravar University of Oxford 2 August 2004 MICE performance with ideal Gaussian beam JUNE04 beam from ISIS beamline (Kevin.
1 PID Detector Size & Acceptance Chris Rogers Analysis PC 04-05-06.

1 PID Detector Size & Acceptance Chris Rogers Analysis PC
WIN'05, June 7 2005A. Klier - Muon Collider Physics1 Physics at a Future Muon Collider Amit Klier University of California, Riverside WIN’05 – Delphi,

WIN'05, June A. Klier - Muon Collider Physics1 Physics at a Future Muon Collider Amit Klier University of California, Riverside WIN’05 – Delphi,
Mark Rayner, Analysis workshop 4 September ‘08: Use of TOFs for Beam measurement & RF phasing, slide 1 Use of TOFs for Beam measurement & RF phasing Analysis.

Mark Rayner, Analysis workshop 4 September ‘08: Use of TOFs for Beam measurement & RF phasing, slide 1 Use of TOFs for Beam measurement & RF phasing Analysis.
Helical Cooling Channel Simulation with ICOOL and G4BL K. Yonehara Muon collider meeting, Miami Dec. 13, 2004 Slide 1.

Helical Cooling Channel Simulation with ICOOL and G4BL K. Yonehara Muon collider meeting, Miami Dec. 13, 2004 Slide 1.
Chris Rogers, Analysis Parallel, MICE CM17 Progress in Cooling Channel Simulation.

Chris Rogers, Analysis Parallel, MICE CM17 Progress in Cooling Channel Simulation.
1 Chris Rogers MICE Collaboration Meeting 11th Feb 2005 Tracking and Cooling performance of G4MICE.

1 Chris Rogers MICE Collaboration Meeting 11th Feb 2005 Tracking and Cooling performance of G4MICE.
FFAG Concepts and Studies David Neuffer Fermilab.

FFAG Concepts and Studies David Neuffer Fermilab.
1 Front End Capture/Phase Rotation & Cooling Studies David Neuffer Cary Yoshikawa December 2008.

1 Front End Capture/Phase Rotation & Cooling Studies David Neuffer Cary Yoshikawa December 2008.
June 21, 2005 S. Kahn -- Small Muon Cooling Ring1 Small Muon Ring for a Cooling Demonstration Steve Kahn For S. Kahn, H. Kirk, A. Garren, F. Mills and.

June 21, 2005 S. Kahn -- Small Muon Cooling Ring1 Small Muon Ring for a Cooling Demonstration Steve Kahn For S. Kahn, H. Kirk, A. Garren, F. Mills and.

Similar presentations

Ads by Google