MiniBooNE : Current Status - PowerPoint PPT Presentation

1 / 27
About This Presentation
Title:

MiniBooNE : Current Status

Description:

5th International Workshop on Neutrino Beams and Instrumentation. 6/26/09 ... Laser Flasks (4) Measure tube Q, timing response ... – PowerPoint PPT presentation

Number of Views:48
Avg rating:3.0/5.0
Slides: 28
Provided by: blah161
Category:

less

Transcript and Presenter's Notes

Title: MiniBooNE : Current Status


1
5th International Workshop on Neutrino Beams and
Instrumentation
  • LSND the significance.
  • Calibration and detector response.
  • Neutrino Physics
  • CCQE
  • CC p
  • NCE
  • The experiment is on track
  • for an oscillation result.

Tank pmts hit gt 200 Veto pmts hit lt 6
__
__________________
Booster n Beam
The Status of MiniBooNE Ray Stefanski
___
_________ _________
____
2
  • Implications of LSND
  • How many ?s?
  • new flavors?
  • ?/ ?/ ?R?

3



LSND Dm2 1eV2 q 2

sterile

Atmospheric oscillations Dm2 10-3eV2 q 45
Solar oscillations Dm2 10-5 eV2 q 32
q the mixing angle
4
Theory of Neutrinos R.N. Mohapatra http//www.phys
ics.umd.edu/ep/mohapatra/apsreportshort.pdf
The existing data on neutrinos have already
raised very important questions, such as the very
different mixing angles, that are blazing new
trails in physics beyond that Standard Model.
They are also helping to define sharp questions
to be addressed by near future experiments
Are neutrinos Dirac or Majorana? What is the
absolute mass scale of neutrinos? How small is
?13? How maximal is ?23? Is there CP
Violation in the neutrino sector? Is the mass
hierarchy inverted or normal? Is the LSND
evidence for oscillation true? Are there sterile
neutrino(s)?
(i) search for ßß0? decay, (ii) determination of
the sign of the Dm213, and (iii) measurement of
the value of ?13.
We believe that all support should be given to
MiniBooNE experiment until it provides a complete
resolution of the LSND result.
5
  • 8 GeV proton beam
  • 1.6 ?s pulse, 5 Hz rate from Booster
  • p Be ? mesons
  • Mesons focused by magnetic horn
  • focusing increases ? flux by factor of 6
  • allow ?, anti-? running
  • Mesons Decay in Flight (DIF)? ?
  • E 700 MeV, L 541 m (L/E 0.77 m/MeV)

6
  • Neutrino candidate rate
  • Neutrino candidates
  • gt200 tank hits
  • lt6 veto hits
  • Constant rate over time
  • c2/d.o.f. 49/53
  • Tests performance of
  • Tank DAQ
  • Calibration stability
  • 610,927 neutrino events
  • recorded so far...
  • 5.8?1020 POT
  • 1.05 neutrino events
  • per 1015 pot.

7
Related Talks During the Workshop
  • Booster Neutrino Beam (Tom Kobilarcik)
  • Secondary Beam (Robert Nelson)
  • Particle Production (Dave Schmitz HARP MB)
  • Particle Production (Michel Sorel HARP K2K)
  • Neutrino Beam Simulation (Eric Zimmerman T2K)
  • Horn (Larry Bartoszek)
  • Horn Exchange (Tom Kobilarcik)
  • LMC (Terry Hart)

8
Particle Identification
  • Identify events using hit topology
  • Use a boosted tree algorithm
  • and ANN to separate e, mu, pi, delta
  • Particle ID Variables
  • Reconstructed physical observables
  • Track length, particle production angle relative
    to beam direction
  • Auxiliary quantities
  • Timing, charge related early/prompt/late hit
    fractions, charge likelihood
  • Geometric quantities
  • Distance to wall

Nuc. Inst and Meth A, Vol 543/2-3
9
Calibration System
Calibration data samples span oscillation
signal energy range
Electron data samples Michel electrons p0
photons
PMTs calibrated with laser system
Cosmic Muons Stopping, through-going Very
important most neutrino events have muons
10
ne nm Flux Determination

Tungsten Scintillator
Scintillating Fiber Tracker
  • LMC spectrometer
  • K decays produce wider
  • angle ? than ? decays
  • a scintillating fiber tracker is used
  • a permanent magnet
  • gives momentum
  • measurement
  • Tungsten scintillator
  • calorimeter seperates
  • protons from muons

Permanent Magnet
LMC ? candidate event
Terry Hart
11
Calibration
  • Laser Flasks (4)
  • Measure tube Q, timing response
  • Change Intensity to study PMT response, and oil
    properties
  • Muon tracker
  • Track direction and entry point test track
    reconstruction in tank
  • Cube System (7)
  • optically isolated scintilation cubes
  • tracker identifies cosmic ?, the subsequent
    Michel electron of known position is used for
    Energy calibration

m tracker
cosmic m
scintillation cube
Michel electron
Electron samples
12
Expected ne sources to test and measure the
detectors response.
Michel electrons fix the detector Energy scale at
low energy 14.8 Energy reconstruction _at_ 50
MeV ?0 mass peak, sets the Energy scale and
resolution at medium Energy
13








Low Energy Electron Samples
Currently used validating e PID!
  • Michel Electrons
  • Ee lt 52MeV
  • Unlimited supply
  • (2 KHz stopping m rate)
  • Also fixes energy scale
  • for calibration
  • 2. nm e Elastic Scattering
  • Ee lt 1000MeV
  • Expect 100 events
  • Purely leptonic
  • small s uncertainty
  • Event selection based on very
  • forward kinematics
  • Typically used to measure sin2qW and mB

Analysis in Progress!
14

High Energy Sample Ee gt1.5 GeV

ne yield from Kaon decay BR( K ? ne)
5 BR( K0 ? ne) 30
15
Relative Location Between NuMI and MB Beams.
16
Neutrinos from NuMI (The E-898 ne calibration
beam)
Neutrino interactions have been observed in the
E-898 detector, generated by neutrinos from the
NuMI beam. MiniBooNE can now claim to be the
worlds first off-axis detector.
  • MB is 111 mrad off the NuMI beam axis, and
  • 750 m away from the NuMI target.
  • MB triggers off the NuMI extraction kicker in
  • the Main Injector.
  • The beam spill contains 5 batches in 8 ms.
  • A few 1000 events are expected in the range
  • 0ltEvisiblelt2 GeV by the 2005
    shutdown.
  • The expected ne ratio is 5 ?
  • should provide thousands
  • of events for calibration
  • and particle ID!
  • The rate of neutrino events is
  • 0.5/pot.
  • About 80 are nm , 15 are nm.
  • 95 of the events come from
  • near the NuMI target.

17
nm Physics
Data Analysis
  • 611,000 neutrino events recorded so far...
  • 5.8?1020 POT
  • 260K CCQE
  • 165K CC ?
  • 105K NC Elastic
  • 45K NC ?0

(CCQE)
(NCE)
(CC ?)
(NC ?0)
18
nm CCQE
  • Were making preliminary comparisons between
    measured distributions and MC expectations
  • Ex Q2 (Sensitive to nuclear effects such as
    Pauli blocking
  • and the Axial Mass.)
  • CCQE are a class of events that
  • are the largest class of events
  • can be used to validate flux,
  • can constrain Intrinsic ?e background due to
  • ? decay
  • Can be used in a search for ?? disappearance
  • for ?m2 0.1 - 10 eV2
  • For event selection we use Fisher
  • discriminant to isolate events with a
  • ?-like Cerenkov ring in final state.

19
CCQE
  • Simple reconstruction with QE kinematics
  • Measure muon energy and angle
  • Reconstruct neutrino energy and Q2

Preliminary
Preliminary
20
CC p
  • Primary background to CCQE analysis
  • All previous measurements at bubble
    chambers, 7000 total evts, all on
    light targets, few
    measurements at low E.
  • Event Selection
  • At least 2 Michels,
  • parent neutrino event
  • in beam spill
  • Separate into close and
  • far Michels based on
  • distance to
  • end of muon track.
  • Close Michels from ?-
  • ?- capture on C
  • ? 2026?1.5 ns
  • Far Michels come
  • from p
  • ? 2197?0.04 ns

221815 ns
205714 ns
21
CC p
  • Simple reconstruction (for now)
  • Assume events are QE with Delta, instead of
    having recoil nucleon
  • Dont use pion information in reconstruction

??
?
W
A
?
A
22
NC p0 Jen Raaf, Cincinnati
  • Background to ?e appearance (dominant mis-ID)
  • ? crucial for distinguishing ??-gt??, ??-gt?s in
  • atmospheric experiments.
  • The angular distribution constrains models for
  • NC ?0 production
  • Event Selection
  • No decay electron, 2 Cerenkov rings gt 40 MeV each
  • signal yield extracted from fit with background
    MC
  • fit assuming 2 rings
  • Examine mass spectrum, kinematics
  • Bin data in kinematic quantities ?0 momentum, E
    asymmetry, angle of ?0 relative to beam, extract
    binned yields
  • Compare distributions to MC expectations

23






NC p0
Errors are shape errors Dark grey flux
errors Light grey optical model
  • ?0 mass is in good agreement with MC.
  • Cos ??0 sensitive to production mechanism
    (coherent is forward,
  • resonant is nearly flat.)
  • Fall-off at high p is reflects the fall-off in
  • neutrino flux.

24
NuFact05 presented by J. Morfin
25
MB oscillation sensitivity for 1021 pot (top)
and 5 X 1020 (bottom) using the energy fit
method. Blue (yellow) is LSNDs 90 (99) CL
allowed region.
26
Conclusion
  • The LSND effect provides a hint of what might be
    a complex and wonderful world of extra neutrinos.
  • MiniBooNE has accumulated 58 of 1021 pot needed
    for 4-5 ? coverage of LSND
  • Already have worlds largest ? dataset in 1 GeV
    range
  • Reconstruction and analysis algorithms are
    working well
  • CCQE compare with flux predictions,
    disappearance analysis
  • CC ? measure cross section
  • NC ?0 measure cross section, analyze coherent
    contribution
  • ?e appearance analysis well under way plan on
    opening box later this year.
  • E-944 is approved to run through 2006, perhaps
    with anti-neutrinos.

27
(No Transcript)
Write a Comment
User Comments (0)
About PowerShow.com