Post on 24-Aug-2020
INO and its Physics Possibilities
Raj Gandhi∗
Harish-Chandra Research Institute, Allahabad, India* For the INO Collaboration
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.1/43
Introduction. . .
The INO Detector is a proposed 50-100 kT magnetized IronCalorimeter , to be located in PUSHEP, in the Southern part ofIndia.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.2/43
Introduction. . .
The INO Detector is a proposed 50-100 kT magnetized IronCalorimeter , to be located in PUSHEP, in the Southern part ofIndia.
The INO Collaboration presently consists of about 60 people fromsixteen institutes and universities across India.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.2/43
Introduction. . .
The INO Detector is a proposed 50-100 kT magnetized IronCalorimeter , to be located in PUSHEP, in the Southern part ofIndia.
The INO Collaboration presently consists of about 60 people fromsixteen institutes and universities across India.
Work on the prototype, magnet design and detector R and D,simulation,manpower recruitment and training is ongoing.Adetailed Interim Report is available on the INO website http:
www.imsc.res.in
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.2/43
Introduction. . .
The INO Detector is a proposed 50-100 kT magnetized IronCalorimeter , to be located in PUSHEP, in the Southern part ofIndia.
The INO Collaboration presently consists of about 60 people fromsixteen institutes and universities across India.
Work on the prototype, magnet design and detector R and D,simulation,manpower recruitment and training is ongoing.Adetailed Interim Report is available on the INO website http:
www.imsc.res.in
The proposal is under review both domestically and by anInternational panel and a final funding decision is expected verysoon.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.2/43
The Detector
Magnetized calorimeter.
140 horizontal iron plates each 6 cm thick, interspersed withGlass RPC.Modular structure.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.3/43
The Detector. . .
Will fulfill the need of the MONOLITH detector proposed earlier forGran Sasso.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.4/43
The Detector. . .
Will fulfill the need of the MONOLITH detector proposed earlier forGran Sasso.
Technological capabilities for construction/fabrication exist withinthe country, but sufficient trained manpower is a challenging goaltowards which more efforts are needed.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.4/43
The Detector. . .
Will fulfill the need of the MONOLITH detector proposed earlier forGran Sasso.
Technological capabilities for construction/fabrication exist withinthe country, but sufficient trained manpower is a challenging goaltowards which more efforts are needed.
Estimated timescale from approval is 5 years for 50 kT, thoughdesign may allow earlier operation of completed modules
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.4/43
The Detector. . .
Will fulfill the need of the MONOLITH detector proposed earlier forGran Sasso.
Technological capabilities for construction/fabrication exist withinthe country, but sufficient trained manpower is a challenging goaltowards which more efforts are needed.
Estimated timescale from approval is 5 years for 50 kT, thoughdesign may allow earlier operation of completed modules
Estimated cost is about USD 100 million
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.4/43
The Site
Height of peak is 2207 m.
Hydroelectric power project with access roads,large caverns at 500 m depth and13 km of tunnels already adjoin the proposed site, thus Geotechnical knowledge ofarea exists.
Few hours drive from Bangalore International Airport.Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.5/43
Physics Capabilities of INO. . .
INO will essentially be an efficient muon detector with chargeidentification capability. It has the potential to provide useful andsignificant information on the following issues:
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.6/43
Physics Capabilities of INO. . .
INO will essentially be an efficient muon detector with chargeidentification capability. It has the potential to provide useful andsignificant information on the following issues:
Sharpen the precision in atmospheric oscillation parametersand observe the elusive oscillatory dip and rise in the eventrate
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.6/43
Physics Capabilities of INO. . .
INO will essentially be an efficient muon detector with chargeidentification capability. It has the potential to provide useful andsignificant information on the following issues:
Sharpen the precision in atmospheric oscillation parametersand observe the elusive oscillatory dip and rise in the eventrate
Determine the octant of θ23
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.6/43
Physics Capabilities of INO. . .
INO will essentially be an efficient muon detector with chargeidentification capability. It has the potential to provide useful andsignificant information on the following issues:
Sharpen the precision in atmospheric oscillation parametersand observe the elusive oscillatory dip and rise in the eventrate
Determine the octant of θ23
Observe distinct signatures of matter effects and the MassHierarchy in Atmospheric Neutrinos
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.6/43
Physics Capabilities of INO. . .
INO will essentially be an efficient muon detector with chargeidentification capability. It has the potential to provide useful andsignificant information on the following issues:
Sharpen the precision in atmospheric oscillation parametersand observe the elusive oscillatory dip and rise in the eventrate
Determine the octant of θ23
Observe distinct signatures of matter effects and the MassHierarchy in Atmospheric Neutrinos
Make much-needed measurements of VHE muons (10-300TeV) via the pair meter technique
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.6/43
Physics Capabilities of INO. . .
INO will essentially be an efficient muon detector with chargeidentification capability. It has the potential to provide useful andsignificant information on the following issues:
Sharpen the precision in atmospheric oscillation parametersand observe the elusive oscillatory dip and rise in the eventrate
Determine the octant of θ23
Observe distinct signatures of matter effects and the MassHierarchy in Atmospheric Neutrinos
Make much-needed measurements of VHE muons (10-300TeV) via the pair meter technique
Test for CPT violation, Lorentz Invariance and the presence oflong-range forces
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.6/43
Physics Capabilities of INO. . .
In its second phase, INO can function as a detector for a neutrinofactory exploiting the rich physics potential possible with it due toits muon charge identification capability.
Its distances both from CERN (7145 km) and from JHF (6556 km)are close to the magic baseline distance of 7000 km
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.7/43
Physics Capabilities of INO. . .
In its second phase, INO can function as a detector for a neutrinofactory exploiting the rich physics potential possible with it due toits muon charge identification capability.
Its distances both from CERN (7145 km) and from JHF (6556 km)are close to the magic baseline distance of 7000 km
Determination of the mass hierarchy
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.7/43
Physics Capabilities of INO. . .
In its second phase, INO can function as a detector for a neutrinofactory exploiting the rich physics potential possible with it due toits muon charge identification capability.
Its distances both from CERN (7145 km) and from JHF (6556 km)are close to the magic baseline distance of 7000 km
Determination of the mass hierarchy
Detect CP violation in the neutrino sector, in conjunction witha second appropriately positioned detector.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.7/43
Physics Capabilities of INO. . .
In its second phase, INO can function as a detector for a neutrinofactory exploiting the rich physics potential possible with it due toits muon charge identification capability.
Its distances both from CERN (7145 km) and from JHF (6556 km)are close to the magic baseline distance of 7000 km
Determination of the mass hierarchy
Detect CP violation in the neutrino sector, in conjunction witha second appropriately positioned detector.
Improve the precision on θ13 considerably
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.7/43
Measurements of Atmospheric Oscillation Parameters
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.8/43
L/E Dip
Clean detection of L/E dip possible within about 2 years of running.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.9/43
Comparison with Long Baseline Experiments
3σ spread ( ∆m213 = 2 × 10−3 eV2, sin2 θ23 = 0.5).
|∆m213| sin2 θ23
current 44% 39%
MINOS+CNGS 13% 39%
T2K 6% 23%
Nova 13% 43%
INO, 50 kton, 5 years 10% 30%
M. Lindner, hep-ph/0503101
Table refers to the older NOνA proposal;the revised March 2005 NOνA detector isexpected to be competitive with T2K.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.10/43
Comparison with Long baseline Experiments
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.11/43
Is θ23 maximal?
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.12/43
Measuring the Deviation ofθ23 from maximality. . .
The difference between U/D ratios for neutrinos and anti-neutrinosis sensitive to the deviation of θ23 from maximality.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.13/43
Measuring the Deviation ofθ23 from maximality. . .
The difference between U/D ratios for neutrinos and anti-neutrinosis sensitive to the deviation of θ23 from maximality.
A non maximal θ23 has important implications for model building.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.13/43
Measuring the deviation ofθ23 from maximality
S. Choubey and P. Roy, hep-ph/0509197Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.14/43
The Mass Hierarchy, its Significance and Detection
So far we only know |∆m231| and not its Sign
νe
νµ
m12
ντ
m22
m32
m12
δm31
2 δm21
2
m22
Normal ordering (δm31
2 > 0)
m32
Inverted ordering (δm31
2 < 0)
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.15/43
The Mass Hierarchy. . .
The importance of the mass hierarchy lies in its capability todiscriminate between various types of models for unification, and thus in itsability to narrow the focus of the quest for physics beyond theStandard Model.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.16/43
The Mass Hierarchy. . .
The importance of the mass hierarchy lies in its capability todiscriminate between various types of models for unification, and thus in itsability to narrow the focus of the quest for physics beyond theStandard Model.
A large class of GUTS use the Type I seesaw mechanism to unifyquarks and leptons. Several positive features are lost if in suchmodels the neutrino hierarchy is inverted rather than normal
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.16/43
The Mass Hierarchy. . .
The importance of the mass hierarchy lies in its capability todiscriminate between various types of models for unification, and thus in itsability to narrow the focus of the quest for physics beyond theStandard Model.
A large class of GUTS use the Type I seesaw mechanism to unifyquarks and leptons. Several positive features are lost if in suchmodels the neutrino hierarchy is inverted rather than normal
An inverted hierarchy on the other hand would generally requirem1, m2 to be degenerate, hinting towards an additonal global symmetry
in the lepton sector.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.16/43
The Mass Hierarchy. . .
The importance of the mass hierarchy lies in its capability todiscriminate between various types of models for unification, and thus in itsability to narrow the focus of the quest for physics beyond theStandard Model.
A large class of GUTS use the Type I seesaw mechanism to unifyquarks and leptons. Several positive features are lost if in suchmodels the neutrino hierarchy is inverted rather than normal
An inverted hierarchy on the other hand would generally requirem1, m2 to be degenerate, hinting towards an additonal global symmetry
in the lepton sector.
It would also favour theories utilising the Type II seesaw mechanism
with additional Higgs triplets.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.16/43
The Mass Hierarchy. . .
The importance of the mass hierarchy lies in its capability todiscriminate between various types of models for unification, and thus in itsability to narrow the focus of the quest for physics beyond theStandard Model.
A large class of GUTS use the Type I seesaw mechanism to unifyquarks and leptons. Several positive features are lost if in suchmodels the neutrino hierarchy is inverted rather than normal
An inverted hierarchy on the other hand would generally requirem1, m2 to be degenerate, hinting towards an additonal global symmetry
in the lepton sector.
It would also favour theories utilising the Type II seesaw mechanism
with additional Higgs triplets.
The type of hierarchy impacts the effectiveness of leptogenesis inmost theoretical models.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.16/43
Plot of Probabilities. . .
5 10 15
0.20.40.60.8
15 10 15
0.20.40.60.81
0.20.40.60.8
1
0.20.40.60.81
∆m2
31 > 0
Vacuum
∆m2
31 < 0
5 10 15
E (GeV)
00.20.40.60.8
1
5 10 15
E (GeV)
00.20.40.60.81
Pµe
Pµτ
Pµµ
(b) 7000 Km(a) 9700 Km
R. Gandhi et al., Phys. Rev. Lett. 94, 051801 (2005); hep-ph/0411252
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.17/43
Plot of Probabilities. . .
5 10 15
0
0.2
0.4
0.6
0.8
1
Vacuum∆31 > 0∆31 < 0
5 10 15
0
0.2
0.4
0.6
0.8
1
5 10 15
E (GeV)
0
0.2
0.4
0.6
0.8P(ν
µ→ν µ)
5 10 150
0.2
0.4
0.6
0.88000 km 10000 km
6000 km 7000 km
R. Gandhi et al., Phys. Rev. Lett. 94, 051801 (2005); hep-ph/0411252
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.18/43
Measuring the Up/Down Asymmetry
D. Indumathi and M. Murthy,hep-ph/0407336
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.19/43
Plot of Probabilities. . .
5 10 15
0
0.2
0.4
0.6
0.8
1
Vacuum∆31 > 0∆31 < 0
5 10 15
0
0.2
0.4
0.6
0.8
1
5 10 15
E (GeV)
0
0.2
0.4
0.6
0.8P(ν
µ→ν µ)
5 10 150
0.2
0.4
0.6
0.88000 km 10000 km
6000 km 7000 km
R. Gandhi et al., Phys. Rev. Lett. 94, 051801 (2005); hep-ph/0411252
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.20/43
Survival Probability :θ13 sensitivity. . .
5 10 15E (GeV)
0.0
0.2
0.4
0.6
0.8
1.0
Pµµ
0.000.050.100.20
sin2 2θ
13
7000 Km
R. Gandhi et al., hep-ph/0411252
5 10 15E (GeV)
0.0
0.2
0.4
0.6
0.8
1.0
Pµµ
0.000.050.100.20
sin2 2θ
13
9700 Km
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.21/43
Results for an Iron Calorimeter type detector
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.22/43
Results : Iron Calorimeter, 1000 kt-yr. . .
6000 7000 8000 9000
L(Km)
0
5
10
15
20
Nµ- ,
Nµ+
Nµ-m
= 204
Nµ-v = 261
Nµ+m
= 103
Nµ+v = 105
L = 6000 to 9700 Km, E = 5 to 10 GeV
sin2 2θ13 = 0.1
∆31 = 0.002 eV2
R. Gandhi et al., hep-ph/0411252
2.7 2.8 2.9 3 3.1 3.2
Log10L/E [Km/GeV]
0
5
10
15
20
25
Nµ- ,
Nµ+
Nµ-m
= 204
Nµ-v = 261
Nµ+m
= 103
Nµ+v = 105
L = 6000 to 9700 Km, E = 5 to 10 GeV
sin2 2θ13 = 0.1
∆31 = 0.002 eV2
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.23/43
Asymmetry in Up-Down Event Rates. . .
D. Indumathi and M.V.N. Murthy; hep-ph/0407336 Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.24/43
Results : Iron Calorimeter, 1000 kt-yr. . .
8000 8500 9000 9500 10000 10500
L(Km)
8
10
12
14
Nµ-
Nµ-v(0.10) = 175
Nµ-m
(0.05) = 179
Nµ-m
(0.10) = 192
Nµ-m
(0.20) = 223
L = 8000 to 10700 Km, E = 4 to 8 GeV
∆31 = 0.002 eV2
R. Gandhi et al., hep-ph/0411252
3 3.1 3.2 3.3 3.4
Log10L/E [Km/GeV]
0
5
10
15
20
Nµ-
Nµ-v(0.10) = 175
Nµ-m
(0.05) = 179
Nµ-m
(0.10) = 192
Nµ-m
(0.20) = 223
L = 8000 to 10700 Km, E = 4 to 8 GeV
∆31 = 0.002 eV2
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.25/43
Results : Iron Calorimeter, 1000 kt-yr. . .
7000 8000 9000
L(Km)
0.3
0.4
0.5
0.6
0.7
0.8
Up/
Dow
n
mat, ∆31 = +0.002 eV2
mat, ∆31 = -0.002 eV2
vac, ∆31 = +0.002 eV2
L = 6000 to 9700 Km, E = 5 to 10 GeV
sin2 2θ13 = 0.1
R. Gandhi et al., hep-ph/0411252
7000 8000 9000 10000
L (Km)
2
2.5
3
3.5
Nµ- /
Nµ+
matter, ∆31 = +0.002 eV2
vacuum, ∆31 = +0.002 eV2
matter, ∆31 = -0.002 eV2
L = 6000 to 10700 Km, E = 4 to 8 GeV
sin2 2θ13 = 0.1
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.26/43
Bin by bin χ2-analysis
Results for a iron calorimeter detectorχ2 analysis of µ− event in 24 L/E bins15% energy and 15o angular resolution10% systematic error
85% efficiency
Marginalized over ∆m231
, sin2 θ13, sin2 θ23
sin2 2θ13 χ2min
χ2min
500 kt yr 1000 kt yr0.05 2.7 3.70.1 6.6 8.9
Gandhi et al. work in progress.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.27/43
Bin by bin χ2-analysis
Results for a iron calorimeter detectorχ2 analysis of µ− event in 24 L/E bins15% energy and 15o angular resolution10% systematic error
85% efficiency
Marginalized over ∆m231
, sin2 θ13, sin2 θ23
sin2 2θ13 χ2min
χ2min
500 kt yr 1000 kt yr0.05 2.7 3.70.1 6.6 8.9
Gandhi et al. work in progress.
The Importance of Detector Resolution
Petcov and Schwetz,hep-ph/0511277
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.27/43
Bin by bin χ2-analysis
Results for a iron calorimeter detectorχ2 analysis of µ− event in 24 L/E bins15% energy and 15o angular resolution10% systematic error
85% efficiency
Marginalized over ∆m231
, sin2 θ13, sin2 θ23
sin2 2θ13 χ2min
χ2min
500 kt yr 1000 kt yr0.05 2.7 3.70.1 6.6 8.9
Gandhi et al. work in progress.
Comparison with water-Cerenkov detectorNo charge sensitivity: Nµ = N+
µ + N−
µ
sin2 2θ13 χ2min
(6 Mt yr)0.05 1.90.1 4.4
Gandhi et al., hep-ph/0406145
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.27/43
INO as a Detector for VHE Cosmic Ray Muons
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.28/43
Why study VHE muons from CR?
Such studies could help resolve an important open questionregarding the Cosmic Ray Spectrum, i.e. the origin of the knee.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.29/43
Why study VHE muons from CR?
Such studies could help resolve an important open questionregarding the Cosmic Ray Spectrum, i.e. the origin of the knee.
These studies would be very useful for all UHE neutrinotelescopes like AMANDA, ICECUBE etc, since muons andneutrinos at these energies constitute their most importantbackground. At present there is little or no data on the energyspectrum of muons above ∼ 10 TeV.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.29/43
Why study VHE muons from CR?
Such studies could help resolve an important open questionregarding the Cosmic Ray Spectrum, i.e. the origin of the knee.
These studies would be very useful for all UHE neutrinotelescopes like AMANDA, ICECUBE etc, since muons andneutrinos at these energies constitute their most importantbackground. At present there is little or no data on the energyspectrum of muons above ∼ 10 TeV.
These studies would provide crucial data towards understandingthe prompt contribution to VHE muon fluxes
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.29/43
The Pair Meter Technique
Muon energy measurement methods which work well in the GeVrange (magnetic spectrometry or measuring Cerenkov radiation)are rendered impractical in the TeV range primarily due torequirements of size imposed by the combination of high energiesand a steeply falling spectrum.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.30/43
The Pair Meter Technique
Muon energy measurement methods which work well in the GeVrange (magnetic spectrometry or measuring Cerenkov radiation)are rendered impractical in the TeV range primarily due torequirements of size imposed by the combination of high energiesand a steeply falling spectrum.
The pair meter technique skirts some of these difficulties byrelying on a somewhat indirect method, i.e. the measurements ofthe energy and frequency of electron-positron pair cascadesproduced by the passage of a high energy muon in dense matter.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.30/43
The Pair Meter Technique
Muon energy measurement methods which work well in the GeVrange (magnetic spectrometry or measuring Cerenkov radiation)are rendered impractical in the TeV range primarily due torequirements of size imposed by the combination of high energiesand a steeply falling spectrum.
The pair meter technique skirts some of these difficulties byrelying on a somewhat indirect method, i.e. the measurements ofthe energy and frequency of electron-positron pair cascadesproduced by the passage of a high energy muon in dense matter.
The cross section for e+e− pair production by a muon with energyEµ with energy transfer above a threshold E0 grows asln2(2meEµ/mµE0), where mµ and me are the muon and electronmasses respectively.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.30/43
VHE Muon Detection in INO. . .
R. Gandhi and S. Panda , hep-ph/0512179
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.31/43
VHE muons entering INO in 5 years
R. Gandhi and S.Panda, hep-ph/0512179Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.32/43
Cascade production above various thresholds by VHE muons inINO
R. Gandhi and S. Panda, hep-ph/0512179Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.33/43
Bounds on CPT/Lorentz Violation
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.34/43
Sensitivity of Neutrino-Antineutrino Event Ratios to CPT.....
A. Datta et al, hep-ph/0408179Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.35/43
Sensitivity of Neutrino-Antineutrino Event Ratios to CPT.....
A. Datta et al, hep-ph/0408179Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.36/43
The Iron Calorimeter as an End- Detector for a Neutrino Factory
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.37/43
The Utility of a “Magic Baseline Detector”
R. Gandhi and W. Winter, work in progressRaj Gandhi, NNN06, Sep 21 2006, Seattle – p.38/43
The Iron Calorimeter as an End- Detector for a Beta Beam
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.39/43
Physics from a Beta Beam. . .
The proximity to the magic baseline distance leads again tophysics uncluttered by CP degeneracies.
One obtains sensitivity to both the hierarchy and to θ13.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.40/43
Physics from a Beta Beam. . .
The proximity to the magic baseline distance leads again tophysics uncluttered by CP degeneracies.
One obtains sensitivity to both the hierarchy and to θ13.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.40/43
Beta Beam Results...
S. Agarwalla, A. Raychaudhuri and A. Samanta, hep-ph 0505015
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.41/43
Beta Beam results.....
S. Agarwalla, A. Raychaudhuri and A. Samanta, hep-ph 0505015
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.42/43
To Sum Up. . .
INO, a 50-100 kT magnetized iron calorimeter would usefullybuttress the presently planned program of neutrino experimentsworldwide.Using atmospheric neutrinos, a 100 kT detector has the potentialto illuminate one of the most important questions in neutrinophysics, the mass hierarchy
It would provide improved precision on atmospheric neutrinoparameters,improved bounds on CPT/Lorentz violation,crucialdata on VHE muons for the CR and PQCD communities and, in itssecond phase, be an excellent end detector for neutrinofactories/beta beams.At present INO, after an intensive feasibility study, is close to afinal funding decision.
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.43/43
Acknowledgements. . .
I thank my collaborators, A. Datta, P. Ghoshal, S. Goswami, P.Mehta and S. Uma Sankar
Raj Gandhi, NNN06, Sep 21 2006, Seattle – p.44/43