Post on 12-Jan-2016
1
Cosmics at far position
P.Sala, M.Antonello, A.Ferrari, D.Stefan, R.
Sulej
LNGS SC
From report to PAC
LNGS SC Slide: 2
Few trivial things
l Three years of data tacking 6.6 1020 pot 1.4 108 spills 220 sl 4 105 νCC events collected at the far position in positive focusing
mode one every 400 spillsl Signal events are of the order of 600 over three yearsl Intrinsic νe order of 2000 events over three years, ν O 200000
Background “types” and effectsIn a shielded situation, practically ALL background is (re-)generated by
muons l Cosmic photons in coincidence with beam spill
Direct background to nue search, reduce through reconstruction and/or veto (identify associated muon, distinguish nue from photon)
l Cosmic photons inside the drift time, trigger given by another cosmic eventReduce via a light system capable of “segmenting” the LAr volume
and vetol Cosmic events inside drift time, trigger given by neutrino event
Can harm event reconstruction, reduce via light and veto Slide: 3LNGS SC
Simulationsl Two-step FLUKA simulations:l Step 1: showering of primary cosmic rays in atmosphere, at the
FNAL location . Double differential particle fluxes scored at various quotes in atmosphere and at ground.
l Step 2: re-sample these particle distributions on a sphere around the detector and propagation around and inside the detector
Slide: 4
Paola Sala, HSS06
5
Negative muons at floating altitudes: CAPRICE94
Open symbols: CAPRICE data Full symbols: FLUKA
primary spectrum normalization ~AMS-BESS Astrop. Phys., Vol. 17, No. 4 (2002) p. 477
Paola Sala, HSS06 6
L3 Muonsexp. data
FLUKA simulation
Vertical Horizontal
(S.Muraro, PhD thesis Milano)
Paola Sala, HSS06 7
Comparison with AMS data Protons and leptons below the geomagnetic cutoff have been measured by the AMS experiment at altitudes 370-390 Km, latitude ±51.70 Astrop. Phys. 20,221 (2003)
Downgoing proton flux, simulation(solid line) AMS data(triangles). M is the geomagnetic latitude in radians
1st step : fluxes
l particles/cm^2/primary at FNAL elevation (225 m) Neu Pro Pio+ Pio- K0 Muo+ Muo- Pho
Ele Total 5.9E-03 5..6E-04 3.4E-06 4.4E-06 4.9E-08 1.1E-02 8.7E-03 7.4E-03
1.8E-03 E>100 MeV 3.3E-03 4.4E-04 3.2E-06 4.0E-06 4.9E-08 1.1E-02 8.6E-03 2.2E-03
6.9E-04 E>200 MeV 1.5E-03 3.1E-04 2.9E-06 3.5E-06 4.8E-08 1.1E-02 8.4E-03 9.1E-04
3.4E-04 E>1 GeV 1.2E-04 6.8E-05 1.4E-06 1.4E-06 4.0E-08 8.3E-03 6.6E-03 7.7E-05
4.2 E-05
l The photon flux listed here is relevant for un-shielded detectors only
LNGS SC Slide: 8
Step 2
l Simulation restarted at 250m for different particle types, with thresholds at 100 MeV except for muons --> 30 MeV
l Simulated exposure equivalent to about 150s for each particle type (less for muons)
l Configuration 1: detector on surface. Included: non-active LAr, Al, cryo, thermal insulation and its support, ``passerelle'' on top.
l Configuration 2: detector in a pit, covered by 3m of rock. For this configuration, for the moment we have only the contribution from primary MUONS and NEUTRONS, that we expect is the dominant one. the rest is coming.
l Events have been recorded in the usual T600 full simulation, plus some auxiliary data for quick retrieval of information.
LNGS SC Slide: 9
Results underground
Slide: 10
Hz 2m s (drift)
In 220 s
All events, Edep>100 MeV 11600 23 2500000
With ≥ 1 Photon > 100 MeV 570 1.2 120000
With ≥ 1 Photon > 100 MeV, no
1.7 0.003 370
All events, Edep>200 MeV 10700 21 2300000
With ≥ 1 Photon > 200 MeV 250 0.5 56000
With ≥ 1 Photon > 200 MeV, no
0.6 0.001 140l The acquisition and event processing will have to deal with 3 millions of
events, out of which less than one tenth are neutrinosl Every neutrino event will have >5 muon tracks superimposed in the same
chamber (4 chambers)l There will be 56000 photons ON TIME with the spill , 140 of them isolatedl There will be 1.5 million photons with E>200 MeV collected “in drift” (0.5 in
drift times 3 millions triggers) , out of which 3000 have no associated muon
How do neutrino events look like?
Slide: 11
Angular distribution of emitted leptons in the Booster beam
Distribution is wide angle wrt beam is not a good cut for cosmicsWarning for internal veto: 45% of events are NOT contained, need 2 anticoincidence hits to discriminate cosmics
Energy distribution of electrons produced in “signal like” e events. Dashed is the cumulative distribution.200 MeV corresponds to about 10% loss in efficiency
WARNING: Simulation of interactions at these energies is subject to large uncertainties
Zenith of primary
Slide: 12
Zenith angle distribution of primary particle in coincidence with a background event in the detector , underground location.
Dashed line (right axis) is the Cumulative distribution.
Average cosine is 0.778 ,Corresponding to 40 degrees
NOT all the muons are vertical
Deposited energy
LNGS SC Slide: 13
Spectrum of energy deposited by background events in the detector (cut at 100 MeV)
Slide: 14
dN
/d(l
ogE)
GeV
Energy of muons entering the detector
About 15% are stopping inside
Cosmic Photon Energy
Slide: 15
Energy distribution of the most energetic photon in each event, threshold at 100 MeV.
GeV
Photon conversion distance
Slide: 16
Distance of photon conversion vertex from parent muon, in cm, for cosmic background events in t600. Distance is perpendicular to the muon TRACK: it can be used to define a cylindrical “fiducial volume cut” around muon tracks. On the right the cumulative distribution
cm cm
Photon conversion distance
Slide: 17
Distance of photon conversion vertex from parent muon, in cm, for cosmic background events in t600. ONLY photons with E>200 MeV Distance is perpendicular to the muon TRACK: it can be used to define a cylindrical “fiducial volume cut” around muon tracks. On the right the cumulative distribution
At 30 cm 2% are left About 1000 photons “on time” survive, to be reduced through dE/dx or other
cm
Examples
LNGS SC Slide: 18
One background event: isolated photon
Example
Slide: 19
Collection
Induction 2
Background event with one muon + one pion- enteringPion interacts and produces pizero
Pion -
Muon
6630823
Example
Slide: 20
Muon entering from top, accompanied by photon generated ousideNote the dispersion of the em shower the “first” photon is not always the only one to be considered
Wire chambers
Cathode
7379926
Example
LNGS SC Slide: 21
Example
LNGS SC Slide: 22
9897540
One muon can have more than one accompanying photon
Slide: 23
Muon entering from side and crossing, many small photons around
7003983
We generated photons 0-1 GeV along Z directionLook for
• Pair conversions that can mimic a neutrino interaction (activity at the vertex)
• Pair conversions with a “one-mip” like energy deposition• Comptons
Photon identification : preliminary work
• We used the same algorithm that was optimized for the signal type events (FNAL and CERN). The procedure is exactly the same. (see later)
A semi-automatic procedure was used, where the conversion point and the shower direction are taken from MC, the shower reconstruction, topology and dE/dx are automatic
NEXt : apply to simulated background events
Example of event with:• no activity at the vertex• 2 mip
Initial part of the cascade is marked as dark blue:2.5 cm in 3D, dE/dx: 3.97 MeV/cm
OK
Example of event classified as „activity at the vertex”
CollInd 2Ind 1
Collectionenlarged part of the cascade
2 clusters within 3 cm (10 wires)
3 cm
Induction 2 enlarged part of the cascade
dE/dx from 2.5 cm of the initial part of the cascade: 7.48 MeV/cm
• activity at the vertex• > 2 mip
Two other examples classified as events with activity at the vertex.
CollectionInd2
Zoom - CollectionZoom – Ind2
CollectionInd2
Zoom - CollectionZoom – Ind2
dE/dx from 2.5 cm of the initial part of the cascade: 3.96 MeV/cm
dE/dx from 2.5 cm of the initial part of the cascade: 4.8 MeV/cm
for photon momentum > 0.2 GeV/c:• 87% events have no activity at the vtx.• dE/dx > 3.5 MeV/cm:
708events/765events: 93%• dE/dx < 3.5 MeV/cm && activity at the
vtx: 21 events/765 events: 3% (0 comptons)
3.5
MeV
/cm
Info. dE/dx is measured along the higher electron momentum
- photons along z dir.
photons p > 0.2 GeV/c
for photon’s momentum > 0.3 GeV/c:• 88% events have no activity at the
vtx.• dE/dx > 3.5 MeV/cm:
610events/650events: 94%• dE/dx < 3.5 MeV/cm && activity at
the vtx: 16 events/650 events: 2% (0 comptons)
3.5
MeV
/cm
- photons along z dir.
photons p > 0.3 GeV/c
photons p > 0.2 GeV/c
Examples of dangerous photons (slide 7, slide 8, slide 9): dE/dx < 3.5 MeV/cm && activity at the vtx.
Collection
Induction 2
• In total there are 21 events
• 18 are asimmetric as on the event on the left
• 2 photons converted in such a way that the electron with higher momentum goes along collection wire, so they have dE/dx = 0 MeV/cm
• 1 has electromagnetic activity close enough to have more than one cluster at the beginning and dE/dx lower than threshold (3.5 MeV/cm) (slide 9).
Collection Induction 2
Collection - zoom
dark blue: hits taken to compute dE/dx : 2.1 MeV/cm
Collection
Induction 2
Collection - zoom
Two other interesting examples
photon with momentum 0.36 GeV/ce+: 281 MeV/cm and e-: 76 MeV/cm
xprimary vtx
dE/dx = 0 because initial dir of electron with higher energy is along collection wire
3.3 MeV/cm
Only one event this type: 2 clusters within 3 cm and dE/dx lower than 3.5 MeV/cm.
33LNGS SC
Preliminary results from the visual scanning of MC ne events
l Three independent scanners.l Preliminary results on the first 100 events.
Slide: 34
Scanning of intrinsic ne events 100 events
T600: 420 t fiducial mass 91 events
ne events with hadronic activity at vertex 80
ne events with ‘’isolated ‘’ electron candidate
78
ne events with electron at vertex showering
70
Recognized ne MC events 54
As a first hint only ~59% of ne CC MC events with vertex inside the fiducial mass and activity at vertex can be recognized with the previous selection criteria
Results from the scanning of low energy MC ne CC events
l Intrinsic ne spectrum with En < 1.3 GeV (56 %)l Preliminary results on the 175 scanned events.
Slide: 35
Scanning of intrinsic ne events En < 1.3 GeV
175 events
T600: 420 t fiducial mass 160 events
ne events with hadronic activity at vertex 117
ne events with ‘’isolated ‘’ electron candidate
112
ne events with electron at vertex showering
98
Recognized ne MC events 80● only ~50% of ne CC MC events with vertex inside the detector fiducial volume have activity at vertex and can be recognized with the previous selection criteria
● 25 % of the events in the fiducial volume shows no detectable hadronic activity at vertex!
MC event 3 (NO)
Slide: 36
Collection view
Induction1 view
Induction2 view Incoming neutrino
62 cm
43 c
m
142 cm
44 c
m
94 cm
44 c
m
En = 0.51 GeV Edep = 0.49 GeV
l A ne q.e. without activity at interaction vertex.
MC event 8 (OK)
Slide: 37
Collection view
Induction1 view
Induction2 view
94 cm
64 c
m
Incoming neutrino
95 cm
64 c
m
74 cm
60 c
m
En = 1.16 GeVEdep = 0.50 GeV
l DIS event with backward going electron.
LNGS SC Slide: 38