ICARUS: experience from an existing large scale LAr TPC
ICFA 2014 Paris8-10 January 2013
D. GibinDipartimento di Fisica e Astronomia and INFN Padova
For the ICARUS Collaboration
The ICARUS Collaboration
M. Antonelloa, B. Baibussinovb, P. Benettic, F. Boffellic, A. Bubakk, E. Calligarichc, S. Centrob, A. Cesanaf, K. Cieslikg, D. B. Clineh, A.G. Coccod, A. Dabrowskag,
A. Dermenevi, R. Dolfinic, A. Falconec, C. Farneseb, A. Favab, A. Ferrarij, G. Fiorillod, D. Gibinb, S. Gninenkoi, A. Guglielmib, M. Haranczykg, J. Holeczekl,
M. Kirsanovi, J. Kisiell, I. Kochanekl, J. Lagodam, S. Manial, A. Menegollic, G. Mengb, C. Montanaric, S. Otwinowskih, P. Picchin, F. Pietropaolob, P. Plonskio, A. Rappoldic, G.L. Rasellic, M. Rossellac, C. Rubbiaa,j,q, P. Salaf, A. Scaramellif,
E. Segretoa, F. Sergiampietrip, D. Stefana, R. Sulejm,a, M. Szarskag, M. Terranif, M. Tortic, F. Varaninib, S. Venturab, C. Vignolia, H. Wangh, X. Yangh, A. Zalewskag, A.
Zanic, K. Zarembao.a Laboratori Nazionali del Gran Sasso dell'INFN, Assergi (AQ), Italyb Dipartimento di Fisica e Astronomia e INFN, Università di Padova, Via Marzolo 8, I-35131
Padova, Italyc Dipartimento di Fisica Nucleare e Teorica e INFN, Università di Pavia, Via Bassi 6, I-27100
Pavia, Italyd Dipartimento di Scienze Fisiche, INFN e Università Federico II, Napoli, Italye Dipartimento di Fisica, Università di L'Aquila, via Vetoio Località Coppito, I-67100 L'Aquila, Italyf INFN, Sezione di Milano e Politecnico, Via Celoria 16, I-20133 Milano, Italyg Henryk Niewodniczanski Institute of Nuclear Physics, Polish Academy of Science, Krakow,
Polandh Department of Physics and Astronomy, University of California, Los Angeles, USAi INR RAS, prospekt 60-letiya Oktyabrya 7a, Moscow 117312, Russiaj CERN, CH-1211 Geneve 23, Switzerlandk Institute of Theoretical Physics, Wroclaw University, Wroclaw, Polandl Institute of Physics, University of Silesia, 4 Uniwersytecka st., 40-007 Katowice, Polandm National Centre for Nuclear Research,, 05-400 Otwock/Swierk, Polandn Laboratori Nazionali di Frascati (INFN), Via Fermi 40, I-00044 Frascati, Italyo Institute of Radioelectronics, Warsaw University of Technology, Nowowiejska, 00665 Warsaw,
Polandp INFN, Sezione di Pisa. Largo B. Pontecorvo, 3, I-56127 Pisa, Italyq GSSI, Gran Sasso Science Institute, L’Aquila, Italy
The ICARUS single-phase T600 LAr-TPC at LNGS laboratory
Slide: 3
Two identical modules 3.6x3.9x19.6 ≈ 275 m3
each Liquid Ar active mass:
≈476 t Drift length = 1.5 m (1
ms) HV = -75 kV; E = 0.5
kV/cm v-drift = 1.55 mm/μs Sampling time 0.4μs (sub-
mm resolution in drift direction)
4 wire chambers: 2 chambers per module 3 “non-distructive” readout wire planes per chamber wires at 0,±60° (up to 9 m long)
Charge measurement on collection plane≈ 54000 wires, 3 mm pitch and plane spacing
20+54 8” PMTs for scintillation light detection:VUV sensitive (128nm) withTPB wave shifter
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LN2 vessels
readout electronics
T300 T300
cryogenics(behind)
cathode
readout wire arrays
E E
1.5m
The ICARUS T600 detector at LNGS Laboratory
4
2012
2011
2010
· T600 decommissioning @ LNGS is successfully proceeding from June 27th
cryostats empty on July 25th (740 out of 760 tons LAr recovered); detector @ room temperature on September 1st.
· TPC chambers, cryogenic plant, read-out electronics, chimneys,... and ancillary systems will be recovered.
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· Exposed to CNGS beam up to Dec. 3rd 2012: a 8.6 1019 pot event statistics has been collected with a remarkable detector live-time > 93 %.
· In parallel data taking with Cosmics has been conducted to study detector capability for atmospheric , p-decay search (0.73 kty exposure).
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LAr purityWest Cryostat East Cryostat
60
ppt
[O2] e
q
max d
rift
New pump
Recirculation LAr pump faults
New
pu
mp
spee
d in
crea
se
· New Barber Nichols pump successfully tested (Apr – June 2013) allowing to exceed tele > 7ms
· tele > 5ms (~60 ppt [O2] eq):
maximum charge attenuation of 17% at 1.5m
· ele ≈21 ms (≈15 ppt [O2] eq.),
achieved on a 120 liters ICARINO prototype.
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A multi-faceted programme
Our future physics oriented programme is characterized by:
1) Continued analysis of the ≈3000 n events already collected with CNGS2. A main result has been the major clarification of the sterile neutrino search, now concentrated on a small possible window in Dm2
41,, and compatible with the cosmological prediction for dark
matter. More results are also coming.
2) Overhaul of T600 and construction of a smaller T150 detector “clone” under the CERN approved WA104 experiment in view of a short baseline dual detector experiment.
3) This new dual detector configuration installed either at CERN or at FNAL short n-baseline beam will definitively clarify the sterile neutrino questions. It will also ensure the bulk of preparatory phase of the LNBE collaboration, accumulating > 106 n events for test and analysis purposes as a running premise to LBNE.
4) Possible long term utilization of T600 as “near detector” of LBNE. 6ICFA 2014
T600 run at LNGS: first publications1. “Underground operation of the ICARUS T600 LAr-TPC: first results”,
JINST 6 (2011) P07011.
2. “A search for the analogue to Cherenkov radiation by high energy neutrinos at superluminal speeds in ICARUS”, PLB 711 (2012) 270.
3. “Measurement of neutrino velocity with the ICARUS detector at the CNGS beam”, PLB 713 (2012) 17.
4. “Precision measurement of the neutrino velocity with the ICARUS detector in the CNGS beam”, JHEP 11 (2012) 049.
5. “Precise 3D Reconstruction Algorithm for the ICARUS T600 Liquid Argon Time Projection Chamber Detector”, AHEP 2013 (2013) 260820.
6. “Experimental search for the LSND anomaly with the ICARUS detector in the CNGS neutrino beam”, EPJ C73 (2013) 2345.
7. “Search for anomalies in ne appearance from nm beam”, EPJ C73 (2013) 2599.
Analysis of the large amount of physics data becoming progressively the main activity of the CNGS2 collaboration 7ICFA 2014
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A search for LSND effects with ICARUS at CNGS
l There are differences w.r.t. LNSD exp. - L/En ~1 m/MeV at LSND, but
L/E n ≈36.5 m/MeV at CNGS
- LSND -like short distance oscill. signal
averages to sin2(1.27Dm2new L /E)
~1/2 and <P>nm→ne ~ 1/2 sin2(2qnew)
l When compared to other long baseline results (MINOS and T2K) ICARUS operates in a L/E n region in which contributions from n oscillations are not yet too relevant.
l Unique detection properties of LAr-TPC technique allow to identify unambiguously individual e-events with high efficiency.
l The CNGS facility delivered an almost pure nm beam in 10-30 GeV En range (beam associated ne ~1%) at a distance L=732 km from target.
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Selection of ne events
· The “Electron signature” requires: A charged track from primary vertex, m.i.p. on 8 wires,
subsequently building up into a shower; very dense sampling: every 0.02 X0
Isolation (150 mrad) from other ionizing tracks near the vertex in at least one of the TPC views.
· Electron efficiency studied with events from a MC (FLUKA) reproducing in every detail the signals from wire planes: h = 0.74 ± 0.05 (h’ = 0.65 ± 0.06 for intrinsic ne beam due to its harder spectrum).
· ne CC event candidates are visually selected with vertex inside fiducial volume (for shower id.) : > 5 cm from TPC walls and 50 cm downstream
· Energy selection: <30 GeV 50% reduction on intrinsic beam
ne
only 15% signal events rejected
· nm CC events identified by L > 250 cm primary track without had. int.
ne MC event
Search for ne events in CNGS beam
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The new ICARUS resultsl Experimental pictures of one of the four events with a clear electron
signature found in the sample of 1995 n interactions (6.0 1019 pot over the full recorded statistics of 8.6 1019 pot).
l In all events the single electron shower is opposite to hadronic component in the transverse plane.
l The evolution of the actual dE/dx from a single track to an e.m. shower for the electron shower is shown along the individual wires.
l The expected number of e- events from intrinsic νe beam, q13~90 and nm-nt oscillations is then 6.4±0.9 (syst. only).
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1 m.i.p.
2 m.i.p.
1 m.i.p.
2 m.i.p.
θ
Ek = 685 ± 25 MeV
Ek = 102 ± 10 MeV
Collection
mπo = 127 ± 19 MeV/c²θ = 28.0 ± 2.5º
pπo = 912 ± 26 MeV/c
• MC: single electrons (Compton)• MC: e+ e– pairs (g conversions)• data: EM cascades (from p0
decays)
MC
p0 reconstruction:e/ g separation and p0 reconstruction in ICARUS
Mgg:133.8±4.4(stat)±4(syst)
MeV/c2
Unique feature of LAr to distinguish e from g and reconstruct p0
Estimated bkg. from p0 in NC and μ CC : negligible (from MC and scanning)
Sub-GeV E range
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Exclusion of the low energy MiniBooNE experiment
l The ICARUS results exclude the existence of the (otherwise questionable) low energy sterile neutrino peak presented by MiniBooNE both in the neutrino and antineutrino channels. This is also confirmed by OPERA.
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EP
J C
. 73
(2
013)
259
9
● the present ICARUS limit ● the limits of KARMEN ● the positive signals of LSND and MiniBooNE
limit of KARMEN
allowed MiniBooNE
allowed LSND 90%allowed LSND 99%
ICARUS results:E.PJ C 73 (2013) 2599
present ICARUS
exclusion area
ICARUS result strongly limits the window of parameters for a possible LSND anomaly to a very narrow region (Dm2 ≈ 0.5 eV2 and sin22q ≈ 0.005) where there is an overall agreement (90% CL) of
LSND-like exclusion from the ICARUS experiment
13ICFA 2014However the original LSND anomaly requires the direct verification with anti-ns
A new coherence of the global 3+1 fits
l Global fits of sin2qme (appearance) & sin2qee and sin2q mm (disappearance) with corresponding Dm2
41: a well defined common region 0.82<Dm2
41<2.19 eV2 well within expectations of relevant cosmological measurements.
l The crucial indication in favor of short-baseline is still the old LSND result. MiniBooNE experiment has been inconclusive: hence new and better experiments are needed to check the presence of these signals.
l The conditionally approved CERN WA104 experiment will give a definitive answer to the sterile neutrino hypothesis, if the required n and anti-n beams will be available
Giunti, Laveder et al.,arXiv:1308.5288
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ICARUS contribution is relevant in excluding most of the area.
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Question & Comments on Machado talk
●In the above plot, the ICARUS limit is placed at sin2(2θ)~ 4 10-2 (99% CL)
while the published ICARUS result is sin2(2θ)=1.5 10-2 (99% CL) EPJ C73 (2013) 2599:●Apparently the ICARUS sensitivity has been calculated independently
by Machado et al obtaining a result different from that published by the ICARUS collaboration.
●In addition most likely only the first ICARUS result (EPJ C73 (2013) 2345) has considered disregarding the more recent update.
●The OPERA result does not seem to be included as well.
●WARNING: the red allowed appearance region is conflicting with the experimental ICARUS/OPERA limits
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3D reconstruction (example of stopping µ)
Simultaneous 3D polygonal fit 2D hit-to-hit associations no longer needed
Adv.High Energy Phys. 2013 (2013)260820
T300 real event
Induction 2 view
Collection view
Induction 1 view
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Automation of reconstruction· CNGS n event primary vertex: automatic reconstruction Validation with visually identified CNGS vertices algorithm efficiency ~ 97%
· automatic event segmentation algorithmTrack identificationShower identificationReady in 2D, to be extended in 3D
FIRST STAGE, output from segmentation: clusters and verticesCandidates for shower: high density of vertices
Just single hits-> neutron, noise
Deltas are excluded during the clusters merging .
Selected example in green
SECOND STAGE, Track clusters, after merging clusters from the segmentation stage:
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Measurement of muon momentum via multiple scattering In the T600 and in future LAr TPCs, a method to measure the
momentum of escaping μ is needed in order to reconstruct μ CC events
· Deflections due to Multiple Coulomb Scattering (MS) provide such a tool
· Horizontal stopping in the T600 are an excellent benchmark Calorimetric measurement is possible The energy range (0.5-4 GeV) perfectly
matches future short and long baseline experiments
· A sample of 1002 stopping muons from CNGS interactions in the upstream rock has been selected and analyzed
Muon momentum reconstructed by calorimetric measurement for the stopping muon sample
230
6.13
lX
l
p
MeV noiseRMS
The RMS of depends on p and on the meas. error
Slide: 19ICFA 2014
Distribution of momentum by MS pMS vs momentum by calorimetry pcal
MS measured over lm=4 m, and requiring a residual m length of 1 m
Work in progress
Slide: 20
Muon p determination by MS is possible with a resolution ≈ 15% in the momentum range of interest for future LAr TPCs
Calorimetric momentum estimate <1%
3 d reco
Event by event ratio pMS / pcal
Bremsstrahlung
3D reconstructed track with nodes
Filling with estimated dE/dx
Muon “cluster’ used for MS
Identified rays
<PMS/PCal)>= 0.97
s(PMS/PCal) = 0.16
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rays and brem photons excluded for MS determination
The need for a continuing neutrino programme
l The recent, major success of ICARUS-CNGS2 experiment has conclusively demonstrated that LAr-TPC is the leading technology for future short/long baseline accelerator driven neutrino physics.
l INFN has just concluded an important cooperation agreement toward a joint experiment with US-LBNE collaboration, involving the long term realization of a truly large mass, LAr-TPC detector for a search of CP violation in the lepton sector, proton decay and other topics.
l We strongly believe that the exclusive utilization of charged particle beams will be vastly insufficient/unrealistic, at least at the level of development & complexity of our LAr-TPC programme, and to prepare adequately for the long term realization of the LBNE.
l The direct and continued access to a neutrino beam either at CERN or alternatively to FNAL is necessary to maintain the appropriate levels in R&D and participation in physics developments within a “learning” process based on real events and cross sections.
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Next neutrino activitiesl ICARUS will be moved to CERN early 2014 for overhauling and
complemented with a new smaller T150 module “clone” of 1/4 of T600 (WA104).
l A MOU between CERN and the participating institutions (INFN) is under preparation, with the installation of the ICARUS detectors in the “Gargamelle Hall” of the West Area. The duration of this program is of about two years.
l ICARUS will then be operated either at CERN, if a beam will be made available on a reasonable time schedule, or else at FNAL, provided it will be approved, collecting a large n event sample (≥106) at short baseline with appropriate energy for the future LBNE experiment.
l In addition to a definitive clarification of sterile neutrino, the R&D programme in LAr may pave the way to ultimate realization of the LNBE detector f.i. with:
An accurate determination of cross sections in Argon;
The experimental study of all individual CC and NC channels;
The realization of sophisticated algorithms for the most effective identification of the events.
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Slide# : 23
Experimental clarification of n anomalies
l A proposal for a dual baseline experiment has been initially presented at CERN as early as 2009, followed by a number of documents to the SPSC.
l Our proposed experiment, collecting a large amount of data both with neutrino and antineutrino focusing, should be able to give a likely definitive answer to the 4 following queries: the LSND+MiniBooNe both antineutrino and neutrino nm ne
oscillationanomalies; The Gallex + Reactor oscillatory disappearance of the initial -n e
signal, both for neutrino and antineutrinos an oscillatory disappearance maybe present in the nm signal so far
unknownAccurate comparison between neutrino and antineutrino related
oscillatory anomalies, maybe due to CPT violation. l In absence of these “anomalies”, the signals of the detectors should be a
precise copy of each other for all experimental signatures and without any need of Monte Carlo comparisons.
l The beam at CERN represents by far the best alternative for such searches.
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Alternative 1: ICARUS at CERN
Near position: 460 m150t LAr-TPC detector to be build+ magnetic spectrometer
Far position: 1600 mICARUS-T600 detector + magnetic spectrometer
New CERN SPS 2 GeV neutrino facility in North Area
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Slide# : 25
Exploring all channels: expected sensitivity
e-appearance: 1 year μ beam (left)2 year anti-μ beam (right)for 4.5 1019 pot/year,3% syst. uncertainty
μe μe
e/m-disappearance: 1 year μ beam (left)1 year μ + 2 years anti-μ beams (right)
ee
combined “anomalies”: from reactor ns, Gallex and Sage experiments.
LSND allowed region isfully explored in both polarities
In addition:Detector R&D (T150)Neutrino cross sections (huge statistics of e)Event reconstruction“pave the way for future LBL experiments”
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Alternative 2. LAr-TPC alternative at Fermilab
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Proposal has been submitted to move the ICARUS LAr-TPC T600 to FNAL. The optimal location is common to the short baseline neutrino beam, about 700 m from the Booster Beam (BNB), and to the off-axis neutrino flux from the NuMI beam line.
Proposal to FNAL:arXiv:1312.7252
Slide# : 27
expected sensitivity @ FNAL
e-appearance: 3 year μ beam (left)5 year antiμ beam (right)for 2.2 1020 pot/year,4% syst. uncertainty
μe
e-disappearance: 3 year μ beam
Shown also the combined “anomalies”: from reactor ns, Gallex and Sage experiments.
ee
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charge identification with Magnetic Field essential to reduce the large ne
contamination in negative polarity
μe
R&D LAr Programme
l Vigorous technology developments while maintaining the already achieved basic features of T600 will introduce important new features (details in C. Montanari talk) :
Magnetizing LAr
LAr Purification
New thermal insulation
New cold bodies design
Compensating recombination effects
Modification on T600 and new electronics for T150
New light collection system
28ICFA 2014
• Though intended as the near detector for the sterile neutrino search, the T150 is the ideal tool to implement new solutions, especially for introduction of a magnetic field, purification schemes and cryogenics.
• New electronic read-out under development: Same architecture as for T600 but
implementing up-to-date components and new ideas for the layout.
New T150 LAr-TPC
• Present T600 design extended to T150 module (1/4 T600): 2 wire chambers, 3 read-out planes each, field shaping electrodes and cathode, separating 2 drift volumes (1.5 m drift).
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LAr Magnetizationl The introduction of an appropriate magnetic field to the LAr-TPC permits
to further contribute to the progress of LAr technology, allowing the unambiguous determination of the sign and momentum of the secondary charged particles and a greatly improved visibility of the e.m. showers.
l It provides an even closer visual similarity to the one of a “Gargamelle like” bubble chamber, with the added advantage of an accurate calorimetry and dE/dx identification of the tracks.
Slide# : 30ICFA 2014
Example of a 4 GeV e-neutrino event,
with a negative electron, p0 , p+
and proton in the final state
Conclusionsl The recent, major success of ICARUS-CNGS2 experiment has conclusively
demonstrated that LAr-TPC is a leading technology for future short/long baseline accelerator driven neutrino physics.
l Both T600 and T150 LAr-TPC detectors will become operational with the vigorous CERN support (approved experiment WA104) in about two years and ready for a short baseline experiment either ad CERN or at FNAL.
l On a longer time scale, INFN has concluded an important cooperation agreement towards a joint experiment with US-LBNE collaboration, in view of the realization of a large mass LAr-TPC detector.
l The direct/continued access to a neutrino beam either at CERN or FNAL is necessary to maintain the appropriate levels in R&D/participation in physics developments within a “learning” process based on real n events.
l ICARUS is the only operational, physics production scale LAr detector and it shall be so for several years to come. We intend to:contribute to definitely clarify sterile neutrino existence (CERN/FNAL)collaborate with LBNE during the preparation phase and with a large
amount of neutrino events at the appropriate energyUse T600 as a convenient “near detector” in LBNE.
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