summary of 13 measurements and prospects
DESCRIPTION
AAP 2012 meeting, Honolulu Jelena Maricic University of Hawaii October 4, 2012. Summary of 13 Measurements and Prospects. Executive Summary. 13. Summary of 13 measurements from reactors 2011-2012. Daya Bay 13 ~8.7 (~8 zero exclusion) RENO - PowerPoint PPT PresentationTRANSCRIPT
SUMMARY OF 13 MEASUREMENTS AND PROSPECTS
AAP 2012 meeting, Honolulu
Jelena MaricicUniversity of HawaiiOctober 4, 2012
Executive Summary
13
Summary of 13 measurementsfrom reactors 2011-2012 Daya Bay 13 ~8.7 (~8 zero exclusion)
RENO
13 ~9.8 (~6 zero exclusion)
Double Chooz
13 ~9.6 (~3 zero exclusion)
Summary of 13 measurements from beams MINOS T2K
2CP 23
213
213
213
213
213
for δ =0, sin (2θ )=1,
sin (2θ ) = 0.053 at best fit
0.01 < sin (2θ ) < 0.12 at 90% C.L.
sin (2θ ) = 0.094 at best fit
0.03 < sin (2θ ) < 0
normal hierarcy:
inv
.19 at 90% C.L.
sin
erted hierarc
(2θ )
y:
= 0 excluded at 96% C.L.
13 ~7 (NH)13 ~9 (IH)
13 ~9 (NH)13 ~10 (IH)
~2 zero exclusion
~3 zero exclusion
Summary of 13 measurements Global fit from Daya Bay, RENO,
Double Chooz and T2K:
1
2
3
4
N
Fogli, Lisi, Marrone, Montanino, Palazzo, Rotunno: hep-ph/1205.5254 (2012)
Sin2 13 = 0.0241 ± 0.0025 (NH)
Sin2 13 = 0.0244 ± 0.0025 (IH)
13 = 8.9± 0.9(~10% relative uncertainty)
Prospects
13 measured to be non zero with > 7 C.L.
In the next 3 years expected to be known with 5% uncertainty
Going from the unknown to the best measured
neutrino mixing angle: 2003-2012
But there is more to this measurement…
Outline
Introduction
Review of the experiments
Results of measurement 13
Prospects
13
Material adopted from presentations from NOW2012 and ISNP 2012, from members of MINOS, T2K, Double Chooz, Daya Bay and RENO
Introduction
13
Starting point in 2003: CHOOZ
Last non-measured neutrino mixing angle!Only the upper limit
on the value of angle θ13 was set!
CHOOZ experiment constraint:
(e e disappearance exp)
@m2atm = 2.3 10-3 eV2
sin2(2θ13) < 0.15(90% C.L)
CHOOZ experimentR = 1.01 2.8%(stat)2.7%(syst)
e x
M. Apollonio et. al., Eur.Phys.J. C27 (2003) 331-374 M. Apollonio et. al., Eur.Phys.J. C27 (2003) 331-374
13 < 11
13 central to fundamental questions CP-violation phase and mass
hierarchy
12 12 13 13
12 12 23 23
13 13 23 23
cos sin 0 cos 0 sin 1 0 0sin cos 0 0 1 0 0 cos sin
0 0 1 sin 0 cos 0 sin cos
CP
CP
i
i
eU
e
“Solar” 12 ~ 30° “Atmospheric” 23 ~ 45°
(SK + MINOS)“Little mixing angle” 13 < 11° (circa 2011)
(CHOOZ)
Value of θ13 directly influences prospects of measuring CP violation
phase in the weak sector!
13 impacts measurements on ~few 100 m scale and aboveInteresting for nuclear reactor monitoring with neutrinos
Δm221=(7.50+0.19
-0.20)×10-5 eV2
(KamLAND)Δm2
32=(2.32+0.12-0.08)×10-3
eV2 (MINOS)
Hints on 13 from global fits in 2005/2008
Fogli, Lisi, Marrone, Palazzo, Rotunno: hep-ph/0806.2649v2 (2008)
sin2 13 = 0.9+2.3−0.9 ×
10−2Fogli, Lisi, Marrone, Palazzo: hep-ph/0506083 (2005)
sin2 13 = 0.016 ± 0.010
13 ~ 513 ~ 7
Large uncertainty and low non-zero exclusion level.
Global fit from KamLAND in March 2011
KamLAND collaboration:hep-ex/1009.4771
sin2 13 = 0.020 ± 0.016
13 ~ 8
Large uncertainty and low non-zero exclusion level.
Review of 13 experiments
13
13 Measurement Strategies
Use muon neutrinos from accelerator: appearance search for electron neutrinos MINOS T2K
Use electron antineutrinos from nuclear reactor: disappearance search CHOOZ Double Chooz Daya Bay RENO
13 and Beam ExperimentsMINOS
T2K
T2K uses off-axis beams to achieve:-Increased flux near oscillation max-Reduced high energy NC bkg
µ
µ
e
e
13 and Reactor Experiments
Reactor Near Detector Far Detector
MeVm27.1sin2sin1
2312
132
E
LmP ee
Eν ~ 4 MeV
(Flux)L2
L~1.5km
< 14%
No Oscillations
Oscillated
e e
High precision measurement required: systematic error ~0.5%
13 & Beam ExperimentsAppearance probability :
dependences in sin(213), sin(23), sign(m231), -CP phase in [0,2]
13 & Reactor Experiments• <E> ~ a few MeV only disappearance experiments
sin2(213) measurement independent of -CP• P(e e) = 1 - sin2(213)sin2(m2
31L/4E) + O(m221/m2
31) weak dependence in m2
21
• a few MeV e + short baselines negligible matter effects (O[10-4] ) sin2(213) measurement independent of sign(m2
13)
Results of measurement 13 with beams
13
MINOS Experiment
735 kmm
MINOS - Main Injector Neutrino Oscillation Search
Two functionally identical detectors to reduce systematics
Near Detector• 1 km from target• 94 m underground, 225 mwe• Measures the energy spectrum and beam composition
Far Detector• 735 km from target• 700 m underground, 2070
mwe• Re-measures the neutrino
beam composition Near Detector980 tons
Far Detector5,400 tons
Steel/scintillator tracking calorimeters
• Alternate orthogonal orientation planes• Steel absorber 2.54 cm thick• Scintillator strips 4.1 cm wide, 1.0 cm
thick• 1 GeV muons penetrate 28 layers• Longitudinal sampling = 1.4 radiation
lengths• Optical WLS fiber readout to multi-
anode PMTs
Detector Technology
Multi-anode PMT
ExtrudedPS scint.4.1 x 1 cm
WLS fiber
ClearFiber cables
2.54 cm Fe
U V planes+/- 450
Magnetized• <B> = 1.3T• Muon energy from
range/curvature• Distinguish μ+ from μ-
tracks
Neutrino Interactions in Detectors
trans
vers
e di
rect
ion e-
m-
beam directioncolor scale represents energy deposition
m Charged
Currentx Neutral Current e Charged
Current
long μ track & possible hadronic activity at vertex
short with compact EM
shower profile
short with diffuse shower
120 GeV protons
Focusing Horns 2 m
675 m15 m 30 m
m 91.7%m 7.0%
e e 1.3%
Target
Neutrino modeHorns focus π+, K+
Decay Pipeπ-
π+
νμ
νμ
Monte Carlo
Neutrino Mode
Antineutrino Mode
120 GeV protons
Focusing Horns 2 m
675 m15 m 30 m
m 91.7%m 7.0%
e e 1.3%
Target
Neutrino modeHorns focus π+, K+
Decay Pipeπ+
π-
νμ
νμ
Monte Carlo Monte CarloAntineutrino modeHorns focus π-, K-
m 39.9%m 58.1%
e e 2.0%
ν ν
22 2 31
22
3 13sin ( )sin ( ) sin m LPE
1.267 Δθ θμ e
νe Appearance Measurement
eν ν
2
2 2 3123
213sin ( )sin ( ) sin LP
E1.267 Δmθ θμ
sensitive to neutrino mixing angle θ13, δCP, mass ordering
if 0, eCP eP P mm In matter, νe CC scattering modifies oscillation probability ~30% in
MINOS
10.6×1020 POT (ν mode)
Electron Appearance in FHC and RHC Beam
3.3×1020 ( ν mode)ν mode Expected (LEM>0.7): 69.1 (background, if θ13=0) 26.0 (signal, if sin2(2θ13)=0.1)Observe: 88 events
ν mode Expected (LEM>0.7):
10.5 (background , if θ13=0) 3.1 (signal, if sin2(2θ13)=0.1)
Observe: 12 events
Library Event Matching (LEM)
2CP 23
213
213
213
213
213
for δ =0, sin (2θ )=1,
sin (2θ ) = 0.053 at best fit
0.01 < sin (2θ ) < 0.12 at 90% C.L.
sin (2θ ) = 0.094 at best fit
0.03 < sin (2θ ) < 0
normal hierarcy:
inv
.19 at 90% C.L.
sin
erted hierarc
(2θ )
y:
= 0 excluded at 96% C.L.
e Appearance:ν and Combined Contour
● Second generation long-baseline neutrino-oscillation experiment;
● High intensity almost pure m beam from Main Ring in J-PARC is shot toward the Super-Kamiokande detector 295km away.
●
from Tokai to Kamioka
● The physics data-taking started in Jan. 2010, and stopped in March 2011 by the earthquake. Resumed almost a year later.
J-PARC in JAEA
Tokai
Tokyo
Kamioka
KEK
T2K experiment
J-PARC in JAEA
Super-Kamiokande J-PARC
Results of measurement 13 with reactors
13
Locations
DoubleChooz Daya
Bay RENO
ConfigurationsDouble Chooz
Daya Bay
300 mwe115 mwe
1 km400 m
Reactor Neutrino Detection Signature• Reactors as neutrino sources:
N s 1 6NFiss s
1 21011P s 1 Chooz: P =2x4.25 GWth N~2x1021s-1 Neutrino detection via inverse decay
Distinctive two-step signature: -prompt event Photons from e+ annihilation Ee = E- 0.8 MeV + O(Ee/mn) -delayed event Photons from n capture on dedicated nuclei (Gd) t ~ 30 ms E ~ 8 MeVGadolinium
Target:Gd doped scintillator
1 g/l Gd in LS
¹ºe + p+ ! e+ + n
The Double Chooz Far DetectorOuter Veto (OV)plastic scintillator stripsOuter Steel Shielding250 t steel (15 cm)Inner Veto (IV)90 m3 of scintillator in a steel vessel (10 mm) equipped with 78 PMTs (8 inches)Buffer110 m3 of mineral oil in a steel vessel (3 mm) equipped with 390 PMTs (10 inches)γ-Catcher (GC)22.3 m3 scintillator in an acrylic vessel (12 mm)Target10.3 m3 scintillator doped with 1g/l of Gd compound in an acrylic vessel (8 mm)
~7m
Calibration Glove Box
Daya Bay
13 Measurement with DC Far
13
Interaction Cross-Section
• Recalculations of spectra introduced normalization shift; “anomaly”?
• Th.A. Mueller et al, Phys.Rev. C83(2011) 054615.
• P. Huber, Phys.Rev. C84 (2011) 024617
}2,1{
Reactors
,2
exp ,4
),(R
Rf
Rf
Rth
R
p tEtEtP
LN
tEN
Reference Spectra + Bugey4 “Anchor”
Normalize to Total Rate Measurement of Bugey4
}2,1{
Reactors
,2
exp ,4
),(R
Rf
Rf
Rth
R
p tEtEtP
LN
tEN
Reduces reactor normalization uncertainty
from 2.70% to 1.76%
Neutrino Candidate Selection
Prompt signal Evis = [0.7, 12.2] MeV Delayed signal Evis = [6.0, 12.0] MeV Delayed Coincidence Δt = [2, 100] µsec Require Δt μ > 1 msec PMT light noise rejection cuts
• PMT hits approx. homogeneous• PMT hits approx. coincident in time
Multiplicity conditions:• No extra events around signal
Background rejection:• No coincident signal in OV• Require Δt μ > 500 msec if Eμ > 600 MeV
Plus three irreducible backgrounds:• Accidentals• Cosmogenic 9Li• Fast neutrons/stopping muons
Neutrino Candidate Selection
Prompt signal Evis = [0.7, 12.2] MeV Delayed signal Evis = [6.0, 12.0] MeV Delayed Coincidence Δt = [2, 100] µsec Require Δt μ > 1 msec PMT light noise rejection cuts
• PMT hits approx. homogeneous• PMT hits approx. coincident in time
Multiplicity conditions:• No extra events around signal
Background rejection:• No coincident signal in OV• Require Δt μ > 500 msec if Eμ > 600 MeV
Preliminary
Trigger efficiency• Threshold at 400keV (ε=50%)• ε=100% above 700keV
Minimum visible energy of ν signalPrompt
energy cut
Neutrino Candidate Selection
Prompt signal Evis = [0.7, 12.2] MeV Delayed signal Evis = [6.0, 12.0] MeV Delayed Coincidence Δt = [2, 100] µsec Require Δt μ > 1 msec PMT light noise rejection cuts
• PMT hits approx. homogeneous• PMT hits approx. coincident in time
Multiplicity conditions:• No extra events around signal
Background rejection:• No coincident signal in OV• Require Δt μ > 500 msec if Eμ > 600 MeV
Neutrino Candidate Selection
Prompt signal Evis = [0.7, 12.2] MeV Delayed signal Evis = [6.0, 12.0] MeV Delayed Coincidence Δt = [2, 100] µsec Require Δt μ > 1 msec PMT light noise rejection cuts
• PMT hits approx. homogeneous• PMT hits approx. coincident in time
Multiplicity conditions:• No extra events around signal
Background rejection:• No coincident signal in OV• Require Δt μ > 500 msec if Eμ > 600 MeV
Neutrino Candidate Selection
Prompt signal Evis = [0.7, 12.2] MeV Delayed signal Evis = [6.0, 12.0] MeV Delayed Coincidence Δt = [2, 100] µsec Require Δt μ > 1 msec PMT light noise rejection cuts
• PMT hits approx. homogeneous• PMT hits approx. coincident in time
Multiplicity conditions:• No extra events around signal
Background rejection:• No coincident signal in OV• Require Δt μ > 500 msec if Eμ > 600 MeV
Neutrino Candidate Selection
Prompt signal Evis = [0.7, 12.2] MeV Delayed signal Evis = [6.0, 12.0] MeV Delayed Coincidence Δt = [2, 100] µsec Require Δt μ > 1 msec PMT light noise rejection cuts
• PMT hits approx. homogeneous• PMT hits approx. coincident in time
Multiplicity conditions:• No extra events around signal
Background rejection:• No coincident signal in OV• Require Δt μ > 500 msec if Eμ > 600 MeV
• 41% of 9Li BG is rejected by additional muon veto (~5% live-time loss)
• 28% of fast neutron/stop μ BG is rejected by OV anticoincidence
Candidate Rate Variation
Before 9Li reduction cut, no OV anticoincidence applied
Not background-subtracted Rate consistent with expectation
Cross-check: Reconstructed Vertex Position
Events well-localized within target Note: no spatial cuts applied in candidate selection
Detector Calibration
1. PMT and electronics gain non-linearity calibration
LED light injection system2. Correct for position
dependence Spallation neutron H captures
3. Correct for time stability Spallation neutron Gd
captures4. Energy scale Radioactive sources deployed
into ν-target and γ-catcher
Energy Calibration
Neutron Detection EfficiencyEnergy & time window, Gd fraction, spill in/out effects• 252Cf source deployed into ν-target and γ-catcher
BackgroundsAccidentals• Prompt: radiation hit on PMT• Delayed: spallation neutron capture• Prevented by radiopurity & shielding• Measured from off-time windows: 0.261 +/- 0.002 day-1
Cosmogenic 9Li• Prompt: beta emission• Delayed: neutrons from long-lived decays• Measured from Δtμ & spatial muon coincidence: 1.25 +/- 0.54 day-1
Fast-n & Stopping muons• Prompt: proton recoil or muon track• Delayed: neutron capture or muon decay• Measured from high-energy spectrum: 0.67 +/- 0.20 day-1
BackgroundsAccidentals• Prompt: radiation hit on PMT• Delayed: spallation neutron capture• Prevented by radiopurity & shielding• Measured from off-time windows: 0.261 +/- 0.002 day-1
Cosmogenic 9Li• Prompt: beta emission• Delayed: neutrons from long-lived decays• Measured from Δtμ & spatial muon coincidence: 1.25 +/- 0.54 day-1
Fast-n & Stopping muons• Prompt: proton recoil or muon track• Delayed: neutron capture or muon decay• Measured from high-energy spectrum: 0.67 +/- 0.20 day-1
Preliminary
BackgroundsAccidentals• Prompt: radiation hit on PMT• Delayed: spallation neutron capture• Prevented by radiopurity & shielding• Measured from off-time windows: 0.261 +/- 0.002 day-1
Cosmogenic 9Li• Prompt: beta emission• Delayed: neutrons from long-lived decays• Measured from Δtμ & spatial muon coincidence: 1.25 +/- 0.54 day-1
Fast-n & Stopping muons• Prompt: proton recoil or muon track• Delayed: neutron capture or muon decay• Measured from high-energy spectrum: 0.67 +/- 0.20 day-1
BackgroundsAccidentals• Prompt: radiation hit on PMT• Delayed: spallation neutron capture• Prevented by radiopurity & shielding• Measured from off-time windows: 0.261 +/- 0.002 day-1
Cosmogenic 9Li• Prompt: beta emission• Delayed: neutrons from long-lived decays• Measured from Δtμ & spatial muon coincidence: 1.25 +/- 0.54 day-1
Fast-n & Stopping muons• Prompt: proton recoil or muon track• Delayed: neutron capture or muon decay• Measured from high-energy spectrum: 0.67 +/- 0.20 day-1
Red: Best-fit Spectrum Grey: Tagged background eventsWhite: IBD Signal
Check Rate vs. Reactor Power
2 events observed in 0.84 days livetime with both reactors off(= 2.2 event/day)
→ Background rate consistent with estimation
(2.2 ±0.6 event/day)
Best fit to expected rate:sin22θ13 = 0.19 ± 0.06BG rate = 2.9 ± 1.1
event/day arXiv:1207.6632
Summary of Rate Uncertainties
Source Uncertainty w.r.t. signalStatistics 1.1%
Flux 1.7%
Detector
Energy response 0.3%
1.0%Edelay containment 0.7%
Gd fraction 0.3%Δt cut 0.5%
Spill in/out 0.3%Trigger efficiency <0.1%
Target H 0.3%
Background
Accidental <0.1%1.6%Fast-n + stop μ 0.5%
9Li 1.4%
Summary of CandidatesBoth Reactors
OnOne Reactor Pth < 20%
Total
Livetime [days] 139.27 88.66 227.93IBD
Candidates6088 2161 8249
PredictionReactor B1 ν 2910.9 774.6 3685.5Reactor B2 ν 3422.4 1331.7 4754.1
9Li 174.1 110.8 284.9FN & SM 93.3 59.4 152.7
Accidentals 36.4 23.1 59.5Total
Prediction6637.1 2299.7 8936.8
Data divided into two integration periods based on reactor power Allows use of changing signal/background ratio in fit
Double Chooz Prompt
SpectrumData w/ Stat. Error BarsBest Fit Prediction(w/ Syst. Errors)Null Oscillation PredictionBackgrounds
Rate+Shape: sin22θ13= 0.109 ± 0.030 (stat.) ± 0.025 (syst.)χ2/d.o.f. = 42.1/35
Rate-only: sin22θ13 = 0.170 ± 0.035 (stat.) ± 0.040 (syst.)Frequentist analysis: sin22θ13 = 0 excluded at 99.8% (2.9σ)Presented in arXiv:1207.6632, accepted by PRD
RENO 13 Measurement
13
Daya Bay 13 Measurement
13
Result
Summary and Prospects
13
Summary of 13 measurements from beams MINOS T2K
2CP 23
213
213
213
213
213
for δ =0, sin (2θ )=1,
sin (2θ ) = 0.053 at best fit
0.01 < sin (2θ ) < 0.12 at 90% C.L.
sin (2θ ) = 0.094 at best fit
0.03 < sin (2θ ) < 0
normal hierarcy:
inv
.19 at 90% C.L.
sin
erted hierarc
(2θ )
y:
= 0 excluded at 96% C.L.
13 ~7 (NH)13 ~9 (IH)
13 ~9 (NH)13 ~10 (IH)
~2 zero exclusion
~3 zero exclusion
Summary of 13 measurementsfrom reactors Daya Bay (June 2012) 13 ~8.7 (~8 zero exclusion)
RENO (June 2012)
13 ~9.8 (~6 zero exclusion)
Double Chooz
13 ~9.6 (~3 zero exclusion)
Summary of 13 measurements Global fit from Daya Bay, RENO,
Double Chooz and T2K:
1
2
3
4
N
Fogli, Lisi, Marrone, Montanino, Palazzo, Rotunno: hep-ph/1205.5254 (2012)
Sin2 13 = 0.0241 ± 0.0025 (NH)
Sin2 13 = 0.0244 ± 0.0025 (IH)
13 = 8.9± 0.9(~10% relative uncertainty)
Energy Spectra Spectral
shape contains some potentially peculiar features when compared to expectation.
Double Chooz
RENO
Daya Bay sin2(213)=0.12
m2atm= 3.0 10-3 eV2
Far/Near ratiosimulated
Summary and Prospects Better understanding of spectral shape: hint of
new physics?!?
13 measured to be non zero with > 7 C.L. and 10% uncertainty
In the next 3 years expected to be known with 5% uncertainty
Going from the unknown to the best measured neutrino mixing angle: 2003-2012!
THANK YOU!