Optimization for disappearance searches at the VLENF (Very Low Energy Neutrino Factory)
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Optimization for disappearance searches at the VLENF (Very Low Energy Neutrino Factory) IDS-NF plenary meeting April 18-20, 2012 Univ. of Glasgow, UK Walter Winter Universität Würzburg
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Optimization for disappearance searches at the VLENF (Very Low Energy Neutrino Factory). IDS-NF plenary meeting April 18-20, 2012 Univ. of Glasgow, UK Walter Winter Universität Würzburg. TexPoint fonts used in EMF: A A A A A A A A. Contents. Motivation, phenomenology Concept - PowerPoint PPT Presentation
Transcript of Optimization for disappearance searches at the VLENF (Very Low Energy Neutrino Factory)
Optimization for disappearance searches at the VLENF (Very Low Energy Neutrino Factory)
IDS-NF plenary meetingApril 18-20, 2012Univ. of Glasgow, UK
Walter WinterUniversität Würzburg
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Contents
Motivation, phenomenology Concept Geometry and systematics implementation Two-baseline optimization e disappearance
disappearance
Summary
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Motivation: anomalies?
Gallium experiments:electron neutrino disappearance?(Acero, Giunti, Laveder, 2007)
Reactor fluxes, revisited:electron antineutrino disappearance?(Mention et al, 2011; Huber, 2011)
LSND/MiniBOONE:electron antineutrino appearance?(LSND, 2001; MiniBooNE, 2010)
Hints for sterile neutrinos with m2 ~ 1 eV2
To be tested in different channels; electron neutrino/antineutrino disappearance one of the key channels!
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Phenomenology
Typically used by experiments: two-flavor picture:
But what does that mean?
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Example: 3+1 framework Oscillation probabilities:
Well known tension between appearance and disapp. data (appearance disapp. in both channels)
e and disappearance described by different parameters
Since disappearance data ~ |U4|2, app. ~ |U4|4,disappearance (in principle) more sensitive!
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VLENF: Concept/geometry
E ~ 2 – 4 GeV, no muon acceleration VLENF concept (Tunnell, Cobb, Bross, 2011)
Lesson from reactor experiments:Identical near detector to measure flux x cross sections (Giunti, Laveder, Winter, 2009)
E=2 GeV
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Geometry implementation
Near detector will experience geometry effects of beam divergence and extension of straight (assume that divergence muon decay kinematics limited)
Effectof beam
geometry
Effectof straight
(Tang, Winter, 2009; Giunti, Laveder, Winter, 2009)
GLoBESbuilt-in
(point source)
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Systematics implementation
Cross section x efficiencies (shape error)Uncorrelated among bins, fully correlated between near and far detectors; 10%
Fiducial volume errorUncorrelated between detectors, fully correlated among bins; 0.6% (reactor exp.!)
Energy calibration error 0.5% Background uncertainties 35%
[NC backgrounds, mis-ID 10-4; charge mis-ID undefined in two flavor framework!]
Energy resolution 10% sqrt(E) e, or 5% sqrt(E)
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Difference app. – disapp.
Appearance:Background-limited (NC, charge mis-ID)
Disappearance:Limited by signal uncertainty (cross sections, efficiencies, fiducial volume)
Need to rely on a near detector!
Challenge: Oscillations in near detector for m2 >> 10 eV2
Cannot derive an effective systematical error from near detector, need combined fit!
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Impact of geometry
(WW, arXiv:1204.2671)
E=2 GeV,1019 useful
muon decays;e disapp.ND
FD
d=20 + 500 m Large
m2 > 30 eV2 sensitivity destroyed by extension of straight and detector
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Impact of systematics
Shape error (cross sec. x efficiency) limits large m2 > 10 eV2 sensitivity
“Low systematics“: Shape 2%Fid. volume 0.1%, BG 10%Calib 0.1%
Systematics limit 10% error
(WW, arXiv:1204.2671)
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Two-baseline optimization
Optimization depends on m2, somewhat on E Use setup A in the following (good compromise)
E=2 GeV,1019 useful
muon decays
(WW, arXiv:1204.2671)
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e disappearance
Need either E=4 GeV or 1019 useful muon decays/polarity to cover best-fit
Highly competitive compared to alternatives (Sterile neutrino white paper)
Can one improve on “systematics limit“?
(WW, arXiv:1204.2671)
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disappearance
Goes beyond SciBooNE + MiniBooNE by about an order of magnitude
Slightly better than e disappearance (beam spectrum!)
Setup A again good compromise
E=2 GeV,1019 useful
muon decays
(WW, arXiv:1204.2671)
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Different polarities
(WW, arXiv:1204.2671)
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Summary and conclusions VLENF requirements for disappearance:
1019 useful muon decays/polarity or E=4 GeV Far detector, distance ~ 500m – 800m (rather 500m);
consistent with appearance requirements (Tunnell, Cobb, Bross, 2011)
Near detector, identical, as close as possible to source With that: comparison to alternatives:
VLENF can do both e and disappearance, in both polarities VLENF can cover e disappearance best-fit VLENF outperforms basically any alternative setup
( Sterile neutrino white paper)
Open issues: Systematics limit for large m2? Perhaps even shorter decay straight possible?
