Simulation of the decay pion spectroscopy at JLab
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Simulation of the decay pion spectroscopy at JLab
Sept. 6 2010Tohoku Uni. S.Nagao Purpose Experimental outline Geant4 simulation Summary
yield & S/N momentum calibration
detector configuration momentum resolution particle identification yield estimation
Contents
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outline
• talk about weak decay pion spectroscopy of hyper nuclear• realistic simulation about decay pion spectroscopy• focus on the pion from 4ΛH (4 body system)• expected value to perform experiment
decay pion yield S/N ratio momentum calibration momentum resolution particle ID
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What is the decay pion spectroscopy ? (purpose)
• We had established the (e,e’K+) reaction spectroscopy at JLab • We push ahead with hyper nuclear research using electron beam
decay pion spectroscopy Tagspectrometer(FWHM~100keV/c)
deduce massMHYP Mncl
Mπ , pπ
deduce the mass of hyperfragment <momentum resolution 130 keV (FWHM)※ (e,e’K) reaction spectroscopy ~300keV (12ΛB g.s.)
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Hyper nuclei Number of π- two body Decay Events others pπ (two body)(MeV/c)total 1061 17674ΛH π- 4He 760 72% 93 5% 132.94 or 5ΛHe - - - 1204 68% -
What kind of hyperfragment can be measured ?
emulsion data in stopped K- reaction (G. BOHM et al. Nucl. Phys. B4 (1968) 511)
feasibility test ; in Spring 2012 at J-Lab (E08-012 (5days))FWHM 3~4 MeV/cpion from 4ΛH
π- momentum (MeV/c)
12C target (stopped K- π-)
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What should we estimate for the experiment ?
1. decay pion yield2. S/N ratio3. method of momentum calibration4. momentum resolution5. method of particle ID
outline1. decay pion yield2. S/N ratio3. method of momentum calibration4. momentum resolution5. method of particle ID
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yield & S/N1. decay pion yield• π- (139.2 MeV/c) → βγcτ ~ 7.4 m short path length• large solid angle acceptance2. S/Nmain back ground component• scattered electron• muon from pion decay• pion from quasi free Lambda & Sigma decay
cherenkov counter or dE/dx or TOFlocate spectrometer behind of target
ΛtargetπΛπe- beam pp
boost forwarduniform
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Stop range & time of 4ΛH (12C target) (MC simulation)
Kinetic energy(MeV)
Stop time (ns)
Kinetic energy(MeV)
Target thickness (mg/cm2)
Maximum range of 4ΛH ; within targetMaximum stopping time of 4ΛH ; less than 0.1nsIn the case of 10MeV
Target thickness (100mg/cm2)Life time (~0.1 ns)
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momentum calibration
3. momentum calibration of spectrometerThe absolute value of pion momentum must be known (∓30 keV)monochromatic source alpha sourcenear by pion momentum (~130MeV/c)
spectrometer
focal plane (FP)Vacuum areaalpha source position at FP
momentumsource Energy (MeV) Momentum (MeV/c)148Gd 3.18 154.00230Th 4.617 185.584.684 186.92210Po 5.305 198.93
source Energy (MeV) Momentum (MeV/c)241Am 5.442 201.495.484 202.27242Cm 6.066 212.746.11 213.51
source Energy (MeV) Momentum (MeV/c)148Gd 3.18 154.00230Th 4.617 185.584.684 186.92210Po 5.305 198.93
source Energy (MeV) Momentum (MeV/c)241Am 5.442 201.495.484 202.27242Cm 6.066 212.746.11 213.51
(Decide the mass precision)
Candidate list of alpha source
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Simulation
spectrometer ; Enge type magnetmagnet field ; TOSCA
1. Yield2. S/N ratio3. method of momentum calibration4. momentum resolution5. method of particle ID
geant41. Yield2. S/N ratio3. method of momentum calibration4. momentum resolution5. method of particle ID
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Geant4 simulation
target 12C100mg/cm2
Focal Plane (aligned SSD) Drift Chamber(He 50%+ CH4 50%)Vacuum Chamber windowDecay pion Decay pion
Enge Magnet
Hodoscope20mm thicknessPlan 1 (SSD) Plan 2 (DC)
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SSDDC
momentum resolution (simulation)
detect at SSD (500um pitch)
counts detect at DC (He 50% + CH4 50%)
momentum (MeV/c)
• simulate momentum resolution at 132.9 MeV/c pions
SSDDC
multiple scattering effectFWHM = 160 keV/cFWHM = 70 keV/c
momentum (MeV/c)Materials Vacuum chamber window (Mylar 100 um & Kevlar 200 um) Air (1 cm) DC window (Mylar 12.5 um) DC Gas (He + CH4)
simulation simulation
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Hodoscope
PID (simulation)
electron ; reject with water or aerogel cherenkovmuon ; not significant background (less than 30% contamination)
• generate particleratio : pion : electron = 4 : 1angle ; ∓2 degree (uniform)momentum ; 85 MeV/c ~ 145 MeV/c (uniform)
muonpion
Energy deposit (MeV)
Counts electron
energy deposit at hodoscope (t=20mm)simulation
beta
beta distribution behind of hodoscopeaerogelwaterlucite
muonpion electron
simulation
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yieldstopped (K-,π-) ; decay π- from 4ΛH : π- from 12ΛC ground state formation
Progress of Theoretical Physics Supplement No.117 1994
= 3~4 : 1stopped (K-,π-) (12C target)
200 nb/sr(e,e’K+) ; decay π- from 4ΛH : 12ΛB ground state cross section= 3~4 : 1
Progress in Particle and Nuclear Physics 57 (2006) 564
momentum transfer at 12C target
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yield
target ; 12C (100mg/cm2 thickness)beam ; 2.3 GeV 50 uAtagging kaon momentum ; 1.2 GeV/ctagging kaon angle ; 6 degree
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yield
simulation
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yield (simulation)conditionparticle ; pionangle ; ∓ 2deg (uniform)momentum ; 85 MeV/c ~ 145MeV/c (uniform) & 132.9 MeV/c200 (50,000 count) : 1 (250 count)Expected decay pion spectrum detect at SSD (momentum resolution ~70 keV/c)
momentum (MeV/c)
counts simulation
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summary
• We will study about the new method of hyper nuclear formation• Momentum is calibrated by alpha sources• 70 keV/c (SSD) or 160 keV/c (DC) momentum resolution • Adopt aerogel or water cherenkov counter to reject the electrons• Pion from 4ΛH is about 250 count/5days• Feasibility test in Spring 2012
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backup
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4ΛH & 4
ΛHeemulsion data in stopped (K-,π-)
G.Bohm et al. Nucl. Phys. B4 (1968) 511
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4ΛH & 4
ΛHe
Hiyama et al. Phys. Rev. C65 (2002) 011301
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4ΛH & 4
ΛHe
G.Bohm et al. Nucl. Phys. B4 (1968) 511
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4ΛH
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4ΛH rate target dependence
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5ΛHe & 4
ΛHe
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Enge
J.E.SPENCER and H.A.ENGE NIM 49 (1967) 181
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Enge input (raytrace)raytrace ; optical calculation software
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experimental setup
CEBAF Primary Electron Beam
Enge Type Magnet(Enge)
Splitter Magnet K+
Beam Dumpe-’π-
• make lambda hyper nuclear with (e-,e-’K+) reaction• emit π- from weak decay of lambda hyper nuclear• observe π- momentun at Enge Type Magnet• detect K+ at HRS to surppress π- from non-strangeness reaction (e.g. Δ formation)
HRS
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momentum calibration
magnetic field value
position at forcal plane experimental field valueestimate with TOSCA
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TOSCA
about TOSCA• magnetic field calculation software• field value accuracy is about 10-3• can output field value of each cell edge.
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simulation• TOSCA model is based on CAD file.• mean field value is about 0.57 Tesla• output field value every 10mm at x, z direction and 2mm at y direction
1 m
pole2pole1coil
yoke
entrance exityoke
zx
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simulation• TOSCA model is based on CAD file.• mean field value is about 0.57 Tesla• output field value every 10mm at x, z direction and 2mm at y direction
1 m
pole2pole1coil
yoke
entrance exityoke
zx
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momentum resolution (DC Ar 50% + C2H6 50%)
FWHM = 262 keV
MeV/c
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Mechanism of 4ΛH Formation
Formation via Compound Nucleus Recoil energy K- absorption at rest ~ 40 MeV
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alpha observation
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position at FP v.s. theta at generate point (geant4)
momentum (MeV/c)
theta_i (deg)
phi_i (deg)
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position at FP v.s. theta at generate point (raytrace)
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dispersion
Ana range (dp±30%)
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Geant4 simulation (plan2)
target12C100mg/cm2Focal Plane (aligned SSD)
Enge Magnet
Hodoscope20mm thicknessDrift Chamber(He 50%+ CH4 50%)
Primary Electron Beam Vacuum Chamber window
Splitter Magnet
Decay pion
Vacuum Area
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