Transcript pdf

LENS: mLENS Simulations,
Analysis, and Results
B. Charles Rasco
Louisiana State University
on behalf of the
LENS Collaboration
Why Low-Energy Neutrino
Spectroscopy (LENS)?
To get ne energy information from the sun!
Compare the photon luminosity of the sun to the luminosity of pp
and CNO n energy output from the sun.
Measure the CNO n in order to get a direct
measure of the metalicity of the sun.
Why LENS?
What signal are we looking for?
Ee = En-Q
En
497 keV
115 keV
Phys. Rev. Lett. 37, 259 (1976).
ne + 115In 115Sn* + bUse 115In because reaction has a low Q value (~115 keV)
In-loaded (~8% - 10 tons of Indium) liquid scintillator (LAB)
In order to identify the electrons and gammas above background
good position and time resolution are required.
One way to accomplish position resolution is with a 3D segmented detector
such as a scintillation lattice detector. LENS is a 60x60x60 scintillation lattice detector.
(See R. Bruce Vogelaar’s Presentation J9-5)
What is a Scintillation Lattice?
Thin Container Filled with Liquid Scintillator
Container Index of Refraction = n1 (Could be air)
Liquid Scintillator Index of Refraction = n2 > n1
What is a Scintillation Lattice?
We call this a Scintillation Lattice
(Though this animation just shows a Scintillation Plane)
What Is LENS?
(See Z. Yokley’s Presentation - J9-6)
mLENS and miniLENS
mLENS - 6x6x6 – 3” Cubes – Now
miniLENS - 9x9x9 – 3” Cubes – Under Construction
4 m Water Tank
LENS – mLENS and miniLENS will show the way...
(See D. Rountree’s Presentation J9-7)
What Was Measured?
Trigger PMT
~.5 mCi 137Cs Source Located Near Center
Bottom of mLENS
for ~ 1 hour
Background Run
for ~ 1/2 hour
Y=5 Plane
Y=4 Plane
Longer Background Run
for ~ 1 week
Y=3 Plane
Y=2 Plane
All Runs Triggered on Center Four Top PMT
~.5 mCi 137Cs Source
PMT All Approximately Normalized by
Previous Measurements
Background Subtracted
Low E Bump
137Cs
(Compton Edge or Full E Deposit?)
137Cs
Data
Raw 137Cs Source (662 keV g)
Background Subtracted 137Cs Source
Background
Normalized
Over This
Region
(1460 keV g)
(Compton Edge or Full E Deposit?)
40K
Thorium (2.6 MeV g)
(Compton Edge or Full E Deposit?)
Simulation of 137Cs Source at Bottom of mLENS
Low Trigger Threshold
Medium Trigger Threshold
High Trigger Threshold
Relative height of low energy bump to high energy bump depends on the trigger level.
Simulation of 137Cs Source at Bottom of mLENS
Low Trigger Threshold
Low Energy Peak is a Low Energy
Deposit in the Plane. Most Likely
Several Mostly Forward Compton
Interactions (The Most Probable to
Happen) in a Single Cell as the g
Crosses the Plane.
High Energy Peak is a Mixture of the
Full Energy Deposit, Full Energy
Minus Loss in the Outer Acrylic
Shell, and the Compton Edge
Deposit in the Plane.
High Trigger Comparison of Simulation and
First 137Cs Measurements
Background Subtracted 137Cs
Simulated 137Cs
Simulated Number of PE / Proportionally Scaled Channel Number
Measured data is proportionally normalized, not linearly normalized.
The LENS Collaboration
VT -- R. Bruce Vogelaar, Mark Pitt, Camillo Mariani, S. Derek Rountree, Laszlo Papp,
Tristan Wright, Joey Heimburger, Lillie Robinson, Zach Yokley
LSU -- Jeff Blackmon, B. Charles Rasco, Liudmyla Afanasieva, Kevin Macon, Matt Amrit
BNL -- Minfang Yeh BNL
NCCU -- Diane Markoff
UNC -- Art Champagne
BACKUP SLIDES
Prediction for 3 Plane mLENS with Low Trigger
Sum Y=2+3+4 Planes
Sum Y=2 Plane
Sum Y=3 Plane
Sum Y=4 Plane
Measurement with Low Trigger Threshold
And What it Translates to Measuring
Prediction for 3 Plane mLENS with High Trigger
Sum Y=2+3+4 Planes
Sum Y=2 Plane
Sum Y=3 Plane
Sum Y=4 Plane
Measurement with High Trigger Threshold
And What it Translates to Measuring