Difference between revisions of "Performance of THGEM as a Neutron Detector"
|Line 51:||Line 51:|
Gaseous detector passed through stages of development to improve signal's width and amplitude. Gaseous detectors started with a gas chamber that contains only a capacitor, a high voltage applied to collect the and after ionization. The disadvantage of that the signal in the order of milliseconds which is very slow for most applications. waiting the electrons to reach the anode, a grid placed between the cathode and the anode to shorten the distance crossed by the electronsstep is important to a Frisch grid detectorFrisch grid detector's pulse width is improved to the microsecond scale. , detector applications increasedwhich necessitated to the model to be a particle counter or a time projector to detect particles that causes less ionization than the heavy ions that previous types were used for, so the wire chambers and proportional counters appeared. They are maany models of them, and they all helped in improving the signal's width and amplitude to suit most of the particle detection applications, specially the ones that require a higher efficiency. But those detectors are not as sensitive as micro-pattern gaseous detectors (MPGD). The MPGD detectors is almost the latest the improvement in gaseous detectors, they are manay tyes od these detectors, and they helped to detect the lower ionizing particles, they depends on ionization followed by electron multiplication by the electric field, such process improved the signal's width to be of the order of nanoseconds, simultaneously the amplitude is increased to go over the background level even when the events are detected even when an accelerator is in operation. PMGD has many types as shown in the figure:
[[File:MPGD_types.jpg | 600px]]
[[File:MPGD_types.jpg | 600px]]
Revision as of 00:23, 14 December 2013
The Performance of a Fission Chamber equipped with Gaseous Electron Multiplier (GEM) Preamplifiers.
I propose to construct and measure the performance of a fission chamber instrumented with preamplifiers known as a Gas Electron Multiplier (GEM). This fission chamber is a chamber filled with a 90/10 Ar/gas mixture enclosing a fissionable target material, like Uranium or Thorium. A neutron of sufficient energy has the potential to interact with fissionable material producing heavy ions known as fission fragments. The fission fragments within 5 micron of the target's surface may escape the target as ions and ionize the gas in the chamber. Electrons freed from the ionization gas can enter the GEM preamplifier producing secondary electrons which are directed to collectors using strong electric fields.
Gas Electron Multiplier (GEM) invented by Fabio Sauli in 1997<ref name="Sauli1997">F. Sauli, et al, NIM A386, (1997) 531-534 </ref >. The GEM preamplifier is a 50 micron sheet of kapton that is coated on each side with 5 micron of copper. The copper clad kapton is perforated with 50-100 micron diameter holes separated by 100-200 micron in a staggered array . Then, THGEM preamplifier is designed as a macroscopic version of GEM that uses a perforated fiberglass board (PC board) clad with a conducting material. A thick fiberglass sheet, that may have up to 10mm thickness, is perforated with holes with a diameter of 2 mm.
GEM detector has been designed, developed and used for detection in CERN since 1997. Fabio Sauli invented the GEM preamplifier in 1997<ref name="Sauli1997">F. Sauli, et al, NIM A386, (1997) 531-534 </ref > and Gandi and De Oliveira designed it. The deign was on 50,5 um kipton copper clad cards, they had holes of 70 um in diameter in a an equilateral triangular pattern with a 140 um pitch distance.
Strong electric fields are established by supplying a potential difference between the two sides of the kapton, or the fiberglass for the case of the THGEM <ref name="Agocs">G. Agocs, B. Clark, P. Martinego, R. Oliveira, V. Peskov,gand P. Picchi,JINST, 3, P020112, 2008 </ref >. The electric field lines transport liberated electrons through the preamplifier holes. For the GEM foils, the smaller diameter of the hole can provide sufficient amplification using a potential difference of 350 V between the two sides. On the other hand, the THGEM with the larger hole diameter requires a higher potential difference of about 2000 Volts to achieve similar amplifications.
Such a high multiplication made them highy desirable to use for complicated experiments such as compass (2007) and TOTEM (2008) for tracking and triggering. /
The objective of this work is to construct a GEM based ionization chamber. The detector will be made sensitive to neutrons by coating the cathode with a fissionable material. The cathode will take a further distance from the first GEM preamplifier than the one used for the original GEM detector design. This fission chamber-like device will have the advantage of measuring the location of the incident neutrons that induced a fission event within the chamber by measuring the ionization signal using a segmented charge collector.
why do we want neutron detector
types of neutron detectors
gaseous neutron detectors
Neutron detectors have many applications in for nuclear, medical, and industrial applications. Researchers and users explore new theories and phenomena that take place when a neutron beam is projected toward a target(s), they collect the data from the detector, and then they analyze it to evaluate the experiment results. For instance, neutrons are extensively used for imaging, which demands a detector with higher efficiency and better spatial resolution to always capture the best image. Fast neutrons are also used for scanning cargo containers: since they are highly penetrating particles, fast neutron detectors can be used for counting and imaging to check the contents of the containers. Finally, the existence of neutron detectors is essential in nuclear reactors, since they are important in determining the reactors’ stability during operation, and in radiation monitoring in the area surrounding the reactor.
There are many types of neutron detectors because of the wide variety of applications; they can be classified depending on the type of neutron interaction, the type of medium that is responsible for producing the signal, or the energy range of detected neutrons. They can also be classified based on their performance which is determined by calculating their efficiency, energy resolution, sensitivity to gamma particles, detector dead time, and spatial resolution. The following table shows some of the neutron detectors and thier characteristics.
|Medium Phase||Signal Generation by||Material Structure||Neutron Energy||Notes|
|Solid||scintillation||Plastic||10-170 MeV||Its length 2m length with a PMT, dopant may decrease the energy range.|
|scintillation||Inorganic, LiBaF3:Ce||Range is dependent on the dopant||Ability to distiguish heavy charged particles.|
|Liquid||scintillation||BC501A||0.004- 8.00 MeV||Liquid scintilators are rarely used, efficiency 1-3 %|
|Gaseous||Ionization||Ar-CO2(70/30)and B-10||< 1 MeV||B-10 is doped on each GEM foil, efficiency may reach to 30% for thermal neutrons|
Gaseous detector have passed through stages of development to improve signal's width and amplitude. Gaseous detectors started with a gas chamber that contains only a capacitor, a high voltage was applied to collect the ions and electrons after ionization. The disadvantage of this was that the signal was in the order of milliseconds which is very slow for most applications. Rather than waiting for the electrons to reach the anode, a grid is placed between the cathode and the anode to shorten the distance crossed by the electrons. This step is important to building a Frisch grid detector. The Frisch grid detector's pulse width is improved to the microsecond scale. Recently, detector applications increased, which necessitated improvements to the model to be a particle counter or a time projector to detect particles that causes less ionization than the heavy ions that previous types were used for, so the wire chambers and proportional counters appeared. They are maany models of them, and they all helped in improving the signal's width and amplitude to suit most of the particle detection applications, specially the ones that require a higher efficiency. But those detectors are not as sensitive as micro-pattern gaseous detectors (MPGD). The MPGD detectors is almost the latest the improvement in gaseous detectors, they are manay tyes od these detectors, and they helped to detect the lower ionizing particles, they depends on ionization followed by electron multiplication by the electric field, such process improved the signal's width to be of the order of nanoseconds, simultaneously the amplitude is increased to go over the background level even when the events are detected even when an accelerator is in operation. PMGD has many types as shown in the figure:
Building a neutron detector based on GEM electrodes has been done for imaging purposes. They are few groups who were interested in constructing neutron detectors for imaging using a neutron flux. To detect the neutrons' signal, most of detectors had a neutron converter based on polyethylene for fast neutrons of energy (1-20 MeV), or B-10 coating for detecting thermal neutrons. The following table shows the properties of the previously built neutron detectors.
|Author||Neutron Type||Converter||n-energy (MeV)||FWHM (mm)||efficeincy||Notes|
|dangendorft||Fast||polypropylene n->p||2-10||0.5-1.0||0.05%( 2 MeV) and 0.02% (7.5 MeV)|||
|F. Murtas||Fast||60 mm polyethylene||2-20||~1.0||at 60 keV||low photon sensitivity |
All the previous detectors meet in low efficiency for detecting the fast and the thermal neutrons. So, the aim of work is to study and build a neutron detector with a higher efficiency for thermal and fast neutrons by installing U-233 thin film,as a fissionable material with a high fission cross section to be a neutron converter, on a cathode surface inside a gaseous chamber contains three GEM preamplifiers.
Fast neutron detectors have many applications in different disciplines of nuclear technology. For instance; fast neutron detectors are used for Homeland security applications, such as neutron imaging for the large size cargo containers, high penetrating neutrons are desirable when efficient fast neutron detectors are available. They are also used for real time measurements of fast neutron beam flux which are used in nuclear reactors such as the Advanced Test Reactor (ATR). The goal of this research is to economically build and test the performance gaseous electron multipliers preamplifiers, as they are installed in detector's chamber that has a coated layer of fissionable material such as U-233.
Decrease time needed to detect fission fragment. (increase the cathode voltage)
Determine the pulse length of a signal from the GEM detector and compare to a fission chamber.
Rad hard pre amplification.
Detecting neutrons with E > 1 MeV?
The detector operation has successive physical processes that governs its performance. The beginning is a neutron induced fission that occurs on U-233 coating surface on the cathode, the fission produces two fission fragment moving back to back,at least one of them will escape from the surface of U-233 coating into the surrounding gas. The fission fragment will move, collide , and ionize the gas, it will exchange charge with the medium's atoms and molecules until it becomes neutral, meanwhile electrons will primarily scatter and they mostly diffuse in the direction of drift electric field which guide them to the first GEM preamplifier. If the electron passed through one of the GEM's preamplifier holes, it will accelerate and ionize the surrounding atoms, that will cause electron multiplication. Then the number of electron increases creating avalanches then streams. The electrons ended their trip as they had been collected by charge collector to create a negative pulse on the oscilloscope display.
Transporting a fission fragment out of the target material and into the gas chamber fission fragment trasport out of U-233
Signals observed from Scope
ToF measurements (Describe the IAC apparatus in the Apparatus section)
"Neutron detectors are used in several diﬀerent applications and are of great importance both in scientiﬁc work as well as in industrial applications, such as nuclear reactors where the reactor neutron ﬂux needs to be monitored. The need for neutron detectors have increased because of the decision to build detectors capable of detecting so called "dirty bombs" in all major harbors in the United States. Also, the scientiﬁc interest has increased because of the construction of the European Spallation Source outside of Lund, where neutrons will be used to study diﬀerent kinds of materials." Linus Ros, Lund University: Faculty of Engineering (LTH), April 4, 2011.
Homeland security application and a need for a large detection area.
A need for detectors that has the ability to discriminate gamma radiation.
low cost and economical stable and robust in harsh radiation areas.
1- Testing the detector in a reactor of a high neutron fluence to study the detector stability and radiation hardness.
Using the ESEM fcor to test the quality of the the procedure for applying ED7100 paste