Gerardo zavala guzman

RISC
CONACYT, Mexico, D.F.

The MINERvA Experiment
November 23th & 24th, 2011

Gerardo Zavala Guzman
(on behalf of the MINERvA Collaboration)

Universidad de Guanajuato
gzg@ugto.mx gzg@fnal.gov
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OUTLINE
The MINERva Collaboration
The MINERvA Detector
The MINERvA Motivations
Current Status
Summary

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The MINERvA Collaboration
At present-day, the
MINERvA Collaboration
is constituted by ca. 120
nuclear and particle
physicists from 22
institutions in 7
countries.

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GOALS:
• Multiple ν-A interaction cross sections (broad
range of A)
• Exclusive final state and differential cross
sections
• Exclusive final states and inclusive scattering.
• Form factors and structure functions
• Nuclear effects on the ν-A interactions

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MINERvA´s Timeline
SUMMARY:
November 2009:
- MINERvA starts taking data with 55% of the detector and
some nuclear targets.

January - March 2010:
- Install remaining detector
- Start taking neutrino data

November 2010:
- Start antineutrino data

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MINERvA´s Timeline (cont.)
2010 and beyond:
Data acquisition for:
LE configuration (3 GeV)
ME configuration (8 GeV)
ν and anti-ν
All targets (H2O, He, C, Fe, Pb)

Special runs to understand the flux
Cross-section experiments
MC Simulations for experimental data
Data processing, validation, etc.
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The NuMI Beam:

not at scale

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a compact, fully
active neutrino
detector that uses
the NuMI beam line
to study neutrino-
nucleus interactions
with unprecedented
detail.

The detector is
directly located
upstream of the
MINOS Near
Detector.

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* Main INjector ExpeRiment for ν-A (interactions)

The MINERvA Detector (cont.)

Main Components:

ν

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The modules:

UX and VX configuration of the scintillator
strips for stereoscopic 3D tracking 11


The modules:

12
done !


The NuMI Beam Characteristics:
♦ Adjustable beam energy of the NuMI ν beam
(broad range νE):
Via target positioning relative to the focusing horns: Peak energy
at 3, 8 and 12 GeV for the LE, ME and HE configurations, resp.

♦ NuMI p+ beam intensity:
∼ <35×1012> P.O.T. per spill at 120 GeV

♦ NuMI p+ beam power:
300-350 kW at ∼0.5 Hz.

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The Optics:

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Spatial resolution:
~ 3 mm
Time resolution:
~ 4 ns
Nuclear targets (broad A):
He, C, H2O, Fe, H2O, Pb
(nuclear effects on ν
interactions absent in free
standing nucleons)
dσ/dE measurements:
QE, DIS, sπ
Recorded POT*:
1.7×1020 neutrinos
0,9×1020 anti-neutrinos

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* as of Fall, 2011

MINERvA Full Detector Events

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The MINERvA Motivations

Main CC Physics Topics:
• Quasi-elastic neutrino scattering
• Resonance production
• Resonance to DIS transition region
• DIS Low Q2 region and structure functions
• Coherent Pion Production
• Strange and Charm particle production
• Nuclear effects from comparisons between
different nuclear targets:
Polystyrene (CH), Carbon, Iron, Lead, H2O, He

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Summary
Experimental Data:

Accumulated:
1.7×1020 POT for neutrino
0.90×1020 POT for antineutrino

The goal: >200 TB
4.9x1020 in LE mode.
12x1020 in ME mode.

Simulation Data (MC):
∼ 15x1020 events

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Summary
MINERvA has unique ability to answer numerous
puzzles seen in current cross section data

MINERvA can effectively select CCQE events

Work ongoing on an increased data set with the
goal of producing CCQE cross section results . . .
pronto !

Expectation: New Understanding of Neutrino
Interactions . . . just around
the corner !
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The MINERvA Collaboration:
D.A.M. Caicedo, C. Castromonte, G.A. Fiorentini, H. da Motta, A. M. Gago, N. Ochoa, C. E. Perez, J. P. Velasquez
J.L. Palomino → Pontificia Universidad Catolica del Peru, Lima, Peru
→ Centro Brasileiro de Pesquisas Físicas, Rio de Janeiro, Brazil S. Boyd, S. Dytman, I. Danko, B. Eberly, Z. Isvan, D. Naples,
C. Simon, B. Ziemer V. Paolone
→ University of California, Irvine, California → University of Pittsburgh, Pittsburgh, Pennsylvania
L. Bagby, D. Boehnlein, R. DeMaat, D.A. Harris*, J. Kilmer, A. Bodek, R. Bradford, H. Budd, J. Chvojka, M. Day, R.
J.G. Morfin, J. Osta, A. Pla-Dalmau, P. Rubinov, D. Schmitz, Flight, H. Lee, S. Manly, K.S. McFarland*, A. McGowan, A.
R. Stefanski Mislivec, J. Park, G. Perdue, J. Wolcott
→ Fermi National Accelerator Laboratory, Batavia, Illinois → University of Rochester, Rochester, New York
J. Grange, J. Mousseau, R. Napora, B. Osmanov, H. Ray G. Kumbartzki, T. Le, R. Ransome#, B. Tice
→ University of Florida, Gainesville, Florida → Rutgers University, New Brunswick, New Jersey
J. Felix, A. Higuera, Z. Urrutia, G. Zavala M. Jerkins, S. Kopp, L. Loiacono
→ Universidad de Guanajuato, Mexico → University of Texas, Austin, Texas
M.E. Christy#, R. Ent, C.E. Keppel, P. Monaghan, T. Walton, H. Gallagher, T. Kafka, W.A. Mann#, W. Oliver
L. Zhu → Tufts University, Medford, Massachusetts
→ Hampton University, Hampton, Virginia M. Aliana, C.J. Solano Salinas
A. Butkevich, S. Kulagin → Universidad Nacional de Ingenieria, Lima, Peru
→ Institute for Nuclear Research, Moscow, Russia W. Brooks, E. Carquina, G. Maggi, C. Peña, I. Potashnikova,
I. Niculescu, G. Niculescu F. Prokoshin
→James Madison University, Harrisonburg, → Universidad Técnica Federico Santa María, Valparaíso,
Virginia E. Maher Chile
→ Massachusetts College of Liberal Arts, North Adams, L. Aliaga, J. Devan, M. Kordosky, J.K. Nelson, J. Walding,
Massachusetts D. Zhang
R. Gran, M. Lanari →The College of William and Mary, Williamsburg, Virginia
→ University of Minnesota-Duluth, Duluth, Minnesota
L. Fields, H. Schellman * Co-Spokespersons
→Northwestern University, Evanston, Illinois # Members of the MINERvA Executive Committee
N. Tagg @ Currently at Universidad Técnica Federico Santa María,
→ Otterbein College, Westerville, Ohio Valparaíso, Chile 24

The MINERvA Detector Plane

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