Barrel Scintillator: Difference between revisions

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== Electronic read-out ==
== Electronic read-out ==
=== Overview ===
The goal of the electronic read-out of the barrel scintillator is to determine the time difference between the signals reaching the two opposite sides of a scintillator bar. Knowing this time difference, it is so possible to calculate the position of each events in the barrel, track the particles if several bars produce a signal, and determine if the event is due to a cosmic ray or an annihilation.
The calculation of the time difference is assured by a Time to Digital Converter (TDC), the TRB_V3 from GSI, which include 5 FPGAs, 256 channels and is able to measure a time with a resolution inferior to 14 ps ([Korcyl 2018]). To achieve the goal of the barrel scintillator, the time difference have to be calculated with a resolution of an order of 200 ps.
Some parts of the waveform of the SiPM signals are recorded too, in order to calculate a time correction based on the amount of photons received by the SiPM. This is ensured by an Analog to Digital Converter (ADC), the Alpha-16 card which support a 100 MHz channel.
In order to produce these data, several electronic cards have been designed:
:- The SiPM board: which support the 6 SiPM for each side of the scintillators bars.
:- The ASD card: ASD stand for Analog Sum Discriminator. This card receive the analog signal from the 6 SiPM amplify and sum these signals. And produce an analog and a digital signal respectively for the ADC and the TDC.
:- The Rear Transition Module (RTM), which distribute the signals to the ADC and the TDC.
:- The Power Distribution Card, which supply the voltage and the threshold level of the discriminator for the ASD card.
All of these parts appears in the following schematic.


= Definitions and Abbreviations =
= Definitions and Abbreviations =

Revision as of 11:13, 23 May 2018

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Table of Figures

Purpose

Antihydrogen annihilation identification in ALPHA crucially depends on the software capability to reject background events, i.e., cosmic rays. Given that the ALPHA-g detectors offer more information than what was available in ALPHA, new and more sophisticated algorithms will be developed to remove backgrounds events. Two types of tools will be deployed: “online” software aimed to monitor antihydrogen production and “machine learning algorithms” to eliminate background from the physics measurements.

While this software will provide the necessary rejection of the cosmic rays, the information collected for making this decision is based on a "Barrel Scintillator" layer surrounding the Radial TPC. Particles traversing this detector will leave a track of light which is recorded in time and intensity. The time correlation between different parts of the Barrel Scint. will permit the identification of the source of the particle.

Scope

Design of the Barrel Scintillator

The barrel scintillator is constituted of 64 scintillators bars and forms a barrel which surround the TPC. The following picture present the design of this barrel.

Light collection with Silicon PhotoMultipliers.

This cylinder is literally a barrel due to the fact that each bar has a trapezoidal section. This reinforce naturally the structural resistance and stability of the cylinder. The amount of bar (64) is a compromised between the acceptable quantity of data, and the azimuth (φ) resolution. The length of each bar is 2.6 meter which is enough to cover the whole 2.4 meter TPC.

Light collection

The scintillators bars are made from EJ200 plastic scintillator from the Texan company Eljen Technology ([Eljen2016]). A particle crossing this scintillator will produce light whose the wavelength is centered around 425 nm. This light is emitted in all direction and reach the Silicone PhotoMultiplier(SiPM) applied on each side of each bar. The silicone Photomultipliers are the 6x6mm MicroFJ-60035 from the company SensL ([SensL2015]). The wavelength of the photon Detection Efficiency peak for these sensors is 420 nm, which correspond to the light emitted by the scintillator. Furthermore these sensors are bias with a low voltage (-30V) and have a small thickness (about 1mm) which make easier their integration in the read-out of the barrel scintillator.

Between the edge of the scintillator bar and the SiPM, a thin thickness (about 1-2 mm) of a transparent silicone rubber have been add in order to prevent any air gap. This silicone rubber is the RTV 615 product with 5% of hardener (by mass) which is commonly used to couple the photo-multipliers tubes to light guides. Previous tests have shown an increase of 30% in the light transmitted to the SiPM with this silicone rubber, in comparison with a set-up without any coupling material. 6 SiPMs are used for the read-out of the light of each edge of the bars. This means approximately 50% of the edge is covered by SiPM. This choice is a compromised between the space constraints (enough space have to be kept to support the weight of each bar), and the fact that the more the light is receive, the better the time resolution is.


Electronic read-out

Overview

The goal of the electronic read-out of the barrel scintillator is to determine the time difference between the signals reaching the two opposite sides of a scintillator bar. Knowing this time difference, it is so possible to calculate the position of each events in the barrel, track the particles if several bars produce a signal, and determine if the event is due to a cosmic ray or an annihilation.

The calculation of the time difference is assured by a Time to Digital Converter (TDC), the TRB_V3 from GSI, which include 5 FPGAs, 256 channels and is able to measure a time with a resolution inferior to 14 ps ([Korcyl 2018]). To achieve the goal of the barrel scintillator, the time difference have to be calculated with a resolution of an order of 200 ps.

Some parts of the waveform of the SiPM signals are recorded too, in order to calculate a time correction based on the amount of photons received by the SiPM. This is ensured by an Analog to Digital Converter (ADC), the Alpha-16 card which support a 100 MHz channel. In order to produce these data, several electronic cards have been designed:

- The SiPM board: which support the 6 SiPM for each side of the scintillators bars.
- The ASD card: ASD stand for Analog Sum Discriminator. This card receive the analog signal from the 6 SiPM amplify and sum these signals. And produce an analog and a digital signal respectively for the ADC and the TDC.
- The Rear Transition Module (RTM), which distribute the signals to the ADC and the TDC.
- The Power Distribution Card, which supply the voltage and the threshold level of the discriminator for the ASD card.

All of these parts appears in the following schematic.

Definitions and Abbreviations

General acronyms or terms used for the ALPHA-g experiment

rTPC Radial Time projection Chamber
z Coordinate along the main axis of the trap and rTPC
φ Azimuthal coordinate, φ = 0 is in direction of cartesian x
θ Angle towards the z-axis
r Radial coordinate in the cylindrical rTPC system
pφ φ component of the pion's original momentum
pθ θ component of the pion's original momentum
GEANT4 GEometry ANd Tracking, particle physics simulation package
Garfield++ Gas detector simulation package

Table 1 – ALPHA-g Abbreviations

References and Related Documents

References
Eljen 2016 Eljen Technology, “General Purpose Plastic Scintillator EJ-200, EJ-204, EJ-208, EJ-212”, January 2016.
SensL 2015 SensL, “J-Series High PDE and Timing Resolution, TSV Package – Datasheet”, 2015.

Studies

Timing resolution

Amplitude correction

Mechanical structure

Description dwg, assembly

Results

trigger on T0 (T1,T2)

T1-T2 position / time reconstruction

Appendix