4,141 research outputs found
Radiation Damage and Recovery Properties of Common Plastics PEN (Polyethylene Naphthalate) and PET (Polyethylene Terephthalate) Using a 137Cs Gamma Ray Source Up To 1 MRad and 10 MRad
Polyethylene naphthalate (PEN) and polyethylene teraphthalate (PET) are cheap
and common polyester plastics used throughout the world in the manufacturing of
bottled drinks, containers for foodstuffs, and fibers used in clothing. These
plastics are also known organic scintillators with very good scintillation
properties. As particle physics experiments increase in energy and particle
flux density, so does radiation exposure to detector materials. It is therefore
important that scintillators be tested for radiation tolerance at these
generally unheard of doses. We tested samples of PEN and PET using laser
stimulated emission on separate tiles exposed to 1 MRad and 10 MRad gamma rays
with a 137Cs source. PEN exposed to 1 MRad and 10 MRad emit 71.4% and 46.7% of
the light of an undamaged tile, respectively, and maximally recover to 85.9%
and 79.5% after 5 and 9 days, respectively. PET exposed to 1 MRad and 10 MRad
emit 35.0% and 12.2% light, respectively, and maximally recover to 93.5% and
80.0% after 22 and 60 days, respectively
Tests of a Digital Hadron Calorimeter
In the context of developing a hadron calorimeter with extremely fine
granularity for the application of Particle Flow Algorithms to the measurement
of jet energies at a future lepton collider, we report on extensive tests of a
small scale prototype calorimeter. The calorimeter contained up to 10 layers of
Resistive Plate Chambers (RPCs) with 2560 1 \times 1 cm2 readout pads,
interleaved with steel absorber plates. The tests included both long-term
Cosmic Ray data taking and measurements in particle beams, where the response
to broadband muons and to pions and positrons with energies in the range of 1 -
16 GeV was established. Detailed measurements of the chambers efficiency as
function of beam intensity have also been performed using 120 GeV protons at
varying intensity. The data are compared to simulations based on GEANT4 and to
analytical calculations of the rate limitations
Tests of a Novel Design of Resistive Plate Chambers
A novel design of Resistive Plate Chambers (RPCs), using only a single
resistive plate, is being proposed. Based on this design, two large size
prototype chambers were constructed and were tested with cosmic rays and in
particle beams. The tests confirmed the viability of this new approach. In
addition to showing an improved single-particle response compared to the
traditional 2-plate design, the novel chambers also prove to be suitable for
calorimetric applications
Measurements of the Rate Capability of Various Resistive Plate Chambers
Resistive Plate Chambers (RPCs) exhibit a significant loss of efficiency for
the detection of particles, when subjected to high particle fluxes. This rate
limitation is related to the usually high resistivity of the resistive plates
used in their construction. This paper reports on measurements of the
performance of three different glass RPC designs featuring a different total
resistance of the resistive plates. The measurements were performed with 120
GeV protons at varying beam intensitie
Characterization of photomultiplier tubes in a novel operation mode for Secondary Emission Ionization Calorimetry
Hamamatsu single anode R7761 and multi-anode R5900-00-M16 Photomultiplier
Tubes have been characterized for use in a Secondary Emission (SE) Ionization
Calorimetry study. SE Ionization Calorimetry is a novel technique to measure
electromagnetic shower particles in extreme radiation environments. The
different operation modes used in these tests were developed by modifying the
conventional PMT bias circuit. These modifications were simple changes to the
arrangement of the voltage dividers of the baseboard circuits. The PMTs with
modified bases, referred to as operating in SE mode, are used as an SE detector
module in an SE calorimeter prototype, and placed between absorber materials
(Fe, Cu, Pb, W, etc.). Here, the technical design of different operation modes,
as well as the characterization measurements of both SE modes and the
conventional PMT mode are reported
Measurement of the Rate Capability of Resistive Plate Chambers
This paper reports on detailed measurements of the performance of Resistive
Plate Chambers in a proton beam with variable intensity. Short term effects,
such as dead time, are studied using consecutive events. On larger time scales,
for various beam intensities the chamber.s efficiency is studied as a function
of time within a spill of particles. The correlation between the efficiency of
chambers placed in the same beam provides an indication of the lateral size of
the observed effects. The measurements are compared to the predictions of a
simple model based on the assumption that the resistive plates behave as pure
resistors
Archimedean-like colloidal tilings on substrates with decagonal and tetradecagonal symmetry
Two-dimensional colloidal suspensions subject to laser interference patterns
with decagonal symmetry can form an Archimedean-like tiling phase where rows of
squares and triangles order aperiodically along one direction [J. Mikhael et
al., Nature 454, 501 (2008)]. In experiments as well as in Monte-Carlo and
Brownian dynamics simulations, we identify a similar phase when the laser field
possesses tetradecagonal symmetry. We characterize the structure of both
Archimedean-like tilings in detail and point out how the tilings differ from
each other. Furthermore, we also estimate specific particle densities where the
Archimedean-like tiling phases occur. Finally, using Brownian dynamics
simulations we demonstrate how phasonic distortions of the decagonal laser
field influence the Archimedean-like tiling. In particular, the domain size of
the tiling can be enlarged by phasonic drifts and constant gradients in the
phasonic displacement. We demonstrate that the latter occurs when the
interfering laser beams are not adjusted properly
Performance of Glass Resistive Plate Chambers for a high granularity semi-digital calorimeter
A new design of highly granular hadronic calorimeter using Glass Resistive
Plate Chambers (GRPCs) with embedded electronics has been proposed for the
future International Linear Collider (ILC) experiments. It features a 2-bit
threshold semi-digital read-out. Several GRPC prototypes with their electronics
have been successfully built and tested in pion beams. The design of these
detectors is presented along with the test results on efficiency, pad
multiplicity, stability and reproducibility.Comment: 16 pages, 15 figure
First test of a power-pulsed electronics system on a GRPC detector in a 3-Tesla magnetic field
An important technological step towards the realization of an ultra-granular
hadronic calorimeter to be used in the future International Linear Collider
(ILC) experiments has been made. A 33X50 cm2 GRPC detector equipped with a
power-pulsed electronics board offering a 1cm2 lateral segmentation was
successfully tested in a 3-Tesla magnet operating at the H2 beam line of the
CERN SPS. An important reduction of power consumption with no deterioration of
the detector performance is obtained when the power-pulsing mode is applied.
This important result shows that ultra-granular calorimeters for ILC
experiments are not only an attractive but also a realistic option.Comment: 10 pages, 9 figure
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