A FORward CALorometer for PHENIX Richard Seto PHENIX – BNL Dec 11, 2008.
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Transcript of A FORward CALorometer for PHENIX Richard Seto PHENIX – BNL Dec 11, 2008.
Last monthFor the defense in AuAu (stage 1, no /0 ) AuAu-Ridge “new” idea (simulation – Ondrej)
Ridge study in AuAu (Edouard does not like calling this ridge studies)
Look at “jet” in FOCAL (eta=1-3) just look at high energy Electromagnetic shower
(trigger on it?) study PID’ed particles in central arms Study particle distribution in VTX
No need for /0 pp – Collins (simulation – Transverse task force, John
L) We can reconstruct two track pi0 up to ~4-5 GeV Do transverse physics
Jet, correlated with two track pi0 (Collins) extract quark transversity (using Belle data)
a couple of Decisions It is argued that Ridge not compelling
enough to get funding Go with transverse physics
4 x-y (=8) strip planes
NSAC milestonesYear # MileStone FOCAL?
2012
DM8 Determine gluon densities at low x in cold nuclei via p+ Au or d + Au collisions.
Required
2013
HP12 (update of HP1)
Utilize polarized proton collisions at center of mass energies of 200 and 500 GeV, in combination with global QCD analyses, to determine if gluons have appreciable polarization over any range of momentum fraction between 1 and 30% of the momentum of a polarized proton.
Low-x required
2014
DM10(new)
Measure jet and photon production and their correlations in A≈200 ion+ion collisions at energies from medium RHIC energies to the highest achievable energies at LHC.DM10 captures efforts to measure jet correlations over a span of energies at RHIC and a new program using the CERN Large Hadron Collider and its ALICE, ATLAS and CMS detectors.
Marginal without FOCAL
2015
HP13 (new)
Test unique QCD predictions for relation between single-transverse spin phenomena in p-p scattering and those observed in deep-inelastic lepton scatteringNew Milestone HP13 reflects the intense activity and theoretical breakthroughs of recent years in understanding the parton distribution functions accessed in spin asymmetries for hard-scattering reactions involving a transversely polarized proton. This leads to new experimental opportunities to test all our concepts for analyzing hard scattering with perturbative QCD.
Required
G
-Jet AuAu
transversephysics
pA physics
Design (4 x-y planes)
Silicon “pads”4 planes of x-y “strips” (8 physical planes)
ParticleDirection
EM0= /0, EM1, EM2 segments, leaves 4-5 cm no room for hadronic segment
22 X0 0.9 (originally NCC was 14 X0 +28 X0 (HAD) 1.4)
4 mm W
old “NCC”
Supertower
γ/π0 Discriminator=EM0 EM1 EM2segments=
bulk geometry, channel count SVX4 chip count
8 layer *128 strips=1024 strips/super-tower 1024 strips/super-tower*160 super-towers/side = 163,840 strips/side 163,840 strips /(128 channels/chip)= 1280 chips/side
Pads 160 supertowers/side*21 detectors/supertower=
3360 detectors/side 3360 detector*16channels/detector= 53760 pads/side
readout channels (pads) 160 supe-rtowers/side *16 pads/tower*3 towers =7680 readouts/side
Bricks (for EM0/EM1/EM2) 2x4:4 2x6:6 2x7:4
This edgeis not in thenew design
Availability History
PHENIX originally bought 16 wafers (or 18?) – for VTX later with help of RIKEN we bought 1.5 extra wafers – for
FOCAL Yields
454 chips per wafer the ratio between versions A and B of chip is 1:4 (VTX uses B)
B is A updated 70% of chips are "good", 10% known bad, 15% probably good
and 5% are probably bad Count:
B: 454*1.5wafers*0.7=476 (*4/5)=380 B and 95 A available to FOCAL
A from VTX: 16wafers*454*0.7*(1/5)=1016 Total possible - 380+95+1016=1491
We know that we can run both A and B versions but we never tested version A. The contentious issue is dynamic range - if it is really the same in both versions we should probably see no difference. I do not expect the answer before end of January - date when we'll probably get new strip sensor control boards available.
Strategy:staging plan NCC
One side EM1+EM2 – cost ~$2M (BNL) (2012) γ/π0 – cost $1-2M (Yonsei/RIKEN/MRI) (2013)
2nd side $2-3M (Yonsei/RIKEN/+??) (2014?)
unsure about 2nd γ/π0
X-view
Y-view
50 GeV pi0
4-x, 2x + vertexlast is overlapping
3-y, 2ylast is overlapping
first look at /0
For the G measurement, after isolation cut, the problem was the /0 separation
needed another factor of ~5 or so
10
Reminder – Hough Tracking All information:
Vertex (assumed to be 0,0,0)
Hit positions (on 8 independent planes)
Hough Track Make slope of all hits with
respect to vertex Fill Histogram
Find Track Track with highest
number of hits associated with it
11
Hough-Hough Tracks Find First-Track
This is the best hough track of all candidates
Although there is no guarantee that the x and y tracks are from the same photon. It does not matter ...
Black points in the histogram
12
Hough-Hough Tracks Find Second-Track
Red points in histogram
Remove hits close to first track
Find second track by ensuring the slope (with respect to center of mass) is opposite.
ignore green line
13
Results Hough-Hough
tracking alone 10 GeV Photons
2 tracks notreconstructed
Same track usedto form inv. mass
γ
14
Results Hough-Hough
tracking alone 10 GeV pi0's
2 tracks notreconstructed
Same track usedto form inv. mass
Mass correctlyreconstructed
π0