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remote_control_experiments:neutron_activation_of_ag [2023-10-03 10:19]
Jon Peter Omtvedt 		remote_control_experiments:neutron_activation_of_ag [2023-10-03 12:09] (current)
Jon Peter Omtvedt
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 Deconvolution of a decay curve with two components\\  Deconvolution of a decay curve with two components\\ 
  
-=== Theory: Neutron Activation of Ag with a Pu/Be n-source ===+==== Theory: Neutron Activation of Ag with a Pu/Be n-source ====
  
 //Neutron Source//\\  //Neutron Source//\\ 
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 I.e. for n-activiation of natural silver we will get: <sup>108m</sup>Ag, <sup>108</sup>Ag, <sup>110m</sup>Ag, and <sup>110</sup>Ag. I.e. for n-activiation of natural silver we will get: <sup>108m</sup>Ag, <sup>108</sup>Ag, <sup>110m</sup>Ag, and <sup>110</sup>Ag.
 \\  \\ 
-=== Experimental procedure: Neutron Activation of Ag ===+==== Experimental Setup ====
  
-//Transport Track and Shielding//\\+//Transport Track//\\
 The Pu/Be source is placed inside paraffin blocks (for slowing down the neutrons to thermal energies). A slide with a holder for the silver plate is pushed back and forth along a track that is 3 m long. One end of the track is inside the paraffin blocks with the n-source. The other end of the track is positioned above a NaI(Tl) detector that measures gamma radiation. A one meter thick concrete wall is separating the n-source and the NaI(Tl) detector to protect the detector (and it's operator) from the neutrons. The track goes through this wall at an angle in such a way that there the radiation around the n-source are not able to escape through the wall.  The Pu/Be source is placed inside paraffin blocks (for slowing down the neutrons to thermal energies). A slide with a holder for the silver plate is pushed back and forth along a track that is 3 m long. One end of the track is inside the paraffin blocks with the n-source. The other end of the track is positioned above a NaI(Tl) detector that measures gamma radiation. A one meter thick concrete wall is separating the n-source and the NaI(Tl) detector to protect the detector (and it's operator) from the neutrons. The track goes through this wall at an angle in such a way that there the radiation around the n-source are not able to escape through the wall. 
  
-Concrete is not very good at shielding against neutrons, but will reduce gamma radiation fields significantly. We therefore must absorb the neutrons before they enter the concrete shielding wall. The absorption typically will utilize a (n,gamma) reaction. I.e. the neutrons are captured and energetic gamma-radiation is emitted. Boron is commonly used for this purpose since it has a very high likelihood to react with (absorb) neutrons. +//Shielding//\\ 
 +Concrete is not very good at shielding against neutrons, but will reduce gamma radiation fields significantly. We therefore must absorb the neutrons before they enter the concrete shielding wall. The absorption typically will utilize a (n,gamma) reaction. I.e. the neutrons are captured and energetic gamma-radiation is emitted. The paraffin moderator can be used for this, but not very effectively. For efficient conversion boron is commonly used since it has a very high likelihood to react with (absorb) neutrons. 
  
-A practical way to put boron around the n-source is to dispersed e.g. boron acid in molten paraffin and cast large shielding blocks. The combination of paraffin and boron will thermalize and capture the neutrons efficiently. These blocks  is placed between the n-source and the concrete wall. The picture below shows the borated paraffin blocks that is arranged around the n-source. The track exits the concrete wall and is protruding into the middle of the borated paraffin shielding structure where the n-source is placed close to the track. +A practical way to put boron around the n-source is to dispersed e.g. boron acid in molten paraffin and cast large shielding blocks. The combination of paraffin and boron will thermalize and capture the neutrons efficiently. These blocks  is placed between the n-source and the concrete wall. 
 + 
 +The advantage of using borate paraffin, is that about 20% of the natural boron is <sup>10</sup>B, which has several orders of magnitude higher cross section for the capture of thermal neutrons than hydrogen (in the paraffin), which can reduce the overall thickness of the shielding. The second advantage is that the process of thermal neutron capture on boron will produce a 0.478 MeV gamma-radiation which would need less lead for attenuation than the 2.225 MeV gamma rays from capture in hydrogen.  
 + 
 +The picture below shows the borate paraffin blocks that is arranged around the n-source. The borate paraffin is more whitish than the pure paraffin block (which are more of a yellow color). The track exits the concrete wall and is protruding into the middle of the borated paraffin shielding structure where the n-source is placed close to the track. 
  
 {{:remote_control_experiments:trackinsideparaffinshielding.jpg?400|}}\\ {{:remote_control_experiments:trackinsideparaffinshielding.jpg?400|}}\\
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 {{:remote_control_experiments:transporttrackanddetectortower.jpg?400|}}\\ {{:remote_control_experiments:transporttrackanddetectortower.jpg?400|}}\\
  
-In this picture you can also see the vacuum control valves that is pushing the silver disc back and forth during your experiments. +In this picture you can also see the vacuum control valves that is pushing the silver disc back and forth during your experiments. Through the mirror you also get a glimpse of the red slide for the silver disk. The webcam is positioned to providing a better picture of this and you enable you to see when the silver disk is in the detector position
  
-Perform five irradiations with the following times: 12, 24, 48, 72, 144 s and measure the resulting decay curves of the two silver isotopes. +==== Experimental Procedure ====
-It is important that you let the silver decay before you perform the subsequent irradiations, possible to use a system such as RoboLab.\\+
  
-\\  +You should perform at least five irradiations. The following durations are suggested: 12, 24, 48, 72, 144 s. You can add measurements if you have time. For each irradiation you will measure gamma radiation between 500 and 750 keV as a function of time. The measurement is provided as number of counts per a preset time interval. The system will automatically measure a sequence of preset intervals. This gives you a measure sequence reflecting the disintegration of the silver isotopes induced by the n-irradiation. 
  
-__How to measure the Decay of n-activated Ag__\\+Your web page to control the RoboLab should look something like this:
  
-//Introduction//\\ +{{:remote_control_experiments:robolabnaacontrolscreen.jpg?600}}\\
-For this part of the exercise, you will use a NaI detector connected to a Multi-Channel Analyzer (MCA) to determine the disintegration rate of the n-activated silver.+
  
-//Principle//\\ +(click on the picture to see a larger version.) You must preset the duration for all the measurement periods (rows in the tablebefore you perform irradiationsIn the beginning you want short intervals to follow the rapid decaythen you switch to longer intervals. We suggest 5x 20 sec followed by 100 sec intervals for the remaining time periods (this will be the defaults when you start up RoboLab)
-This description assumes you have the Maestro MCA software from ORTEC. If you are using an alternative system, you will have to consult the manual to figure out how to use itThe procedure should not be very different, though.\\ +
-We want to make successive 20-s measurements followed by 120-s ones to determine the half-life curve of the silver isotopes. This can be done manually by successive starting-waiting-stopping-saving-clearing operations.\\ +
-However, with a modern system this tiresome procedure can be automated: In Maestro jargon you do this by preparing a job-description file (it would be called a script file or batch file in most other software). This file contain all the instructions you would have to executebut can be simplified by using the built-in loop structure. Furthermore, once running, it will execute the correct commands at exactly the right time.\\ +
-Since the commands execute very rapidly, you will also be able to spend practically all the time actually counting, something witch is not possible if you are doing everything manually.+
  
-Job-description file: +//Background Measurement//\\ 
-  set_preset_real 20\\ +For each irradiation you do, you should continue measuring until the number of counts fluctuate around the background radiation level in the lab. Therefore, before you start irradiations you should perform a background measurement. The easiest way to do this is to select e.g. a 300 sec preset duration for the first row in the table and start counting. Once the system finishes with the first measurement and start measuring counts for the second row in the table you can stop and write down the number of counts obtained for the first row. You then divide the counts by the duration to obtain your background count rate in cps (counts per second)
-  loop 7\\ +
-  clear\\ +
-  start\\ +
-  wait\\ +
-  save m:\spectra\KJM5911_D130_A???.chn\\ +
-  end_loop\\+
  
-  set_preset_real 120\\ +//Performing irradiations//\\ 
-  loop 7\\ +Make sure you have reset the counting duration after the background measurement to whatever you have selected (probably 20 sec). You can now start performing irradiations. Select a preset time in the irradiation control box (to the left) and push the start irradiation button. In the video feed you will see that the slide with the silver disc disappears - it is sent to the neutron irradiation position on the other side of the concrete wall. There is a sensor inside that keeps track of the actual irradiation time. There is also an irradiation indicator light on the control panel. As soon as you see the slide back on top of the detector you start counting by clicking the start counting button (make sure you have cleared the counters before you started the irradiation). The system will now automatically fill in counts in the table and update the start time for each individual measurement interval. Let it run until you are certain you are only measuring background. Write down all the results before clearing the counter for the next irradiation
-  clear\\ +
-  start\\ +
-  wait\\ +
-  save m:\spectra\KJM5911_D130_B???.chn\\ +
-  end_loop\\+
  
-  set_preset_real 300\\ +Repeat the procedure above for all your irradiation times. This will conclude the experimental part of your experiment. Remember that if you start an irradiation that somehow did not work out as expected (e.g. wrong preset time) you //must// wait for the induced radioactivity in the silver disk to die out before making a new attempt. Otherwise the measured activity is not representative for the selected irradiation time
-  clear\\ +
-  start\\ +
-  wait\\ +
-  save m:\spectra\KJM5911_D130_Background.chn\\+
  
-This job-file will perform 8 20-s measurement, then 8 120-s measurements and finally 5-min background measurement. +==== Plotting the Measured Data ==== 
-\\+Use a high-quality data plotting and fitting program (e.g. Origin) to plot and analyze the data. If you use the plotting program to also "fit" the data, i.e. find parameters for two-component decay curve that matches your measurement points in the best possible way, the fitting algorithm must take the uncertainty into account (do not use Excel unless you know how to use the "solver" add-on to do this correctly), otherwise you will get wrong results.
  
-//Procedure//\\ +Notice that you always shall use the 1/3 of the time into each measurement as the "middle time point"This is due to decay after 1/3 of the time you will have equally many counts before and after the 1/3 point (i.e. it is the "middle point".
-The MCA will save spectra containing counts vs. energy. The two interesting gamma-rays from the n-activated silver will overlap and you will not be able to differentiate between them in the NaI spectra. Thus, we will simply use the gross counts and subtract the background as if we had used a simple counter.\\ +
-The procedure for measuring each irradiated silver disk is as follows: +
-  -Measure a background spectrum for as long as possible if you have not already done this. +
-  -Get the irradiated silver disk and put it as quickly as possible on top of the detector. +
-  -Start the job-file and note down the time between end-of-irradiation and starting the job-file. +
-  -Now, sit back and relax! Alternatively (better), if the job-file is saving spectra to a network disk, you can analyze the spectra as they are produced (using another pc which can read the same disk). +
-  -When the job-file finishes, repeat the measurement for the different irradiation times (irradiation times = 12, 24, 48, 72, and 144 s)(Remember to rename or move your spectra, otherwise they will be deleted or the job-file stops.)+
  
-From the spectra you should get the following data (by opening each spectrum in Maestro)The measurement start time and the gross count (total number of counts in the spectrum). Use the "sumcommand to get the total number of counts (the spectrum must contain no region-of-interest markings).\\ +For each irradiation interval plot your data as follows 
 +  * For each data point calculate the net count (gross count minus background count), the uncertainty of the net count (based on uncertainty of both the gross count and the background count).  
 +  * Enter your data in a table ("worksheetif you use Origin) or whatever your plotting program uses: Include measurement time (relative to end of irradiation) as x-value, the net count as y-value, and the uncertainty as y-error. 
 +  * Plot the data - does it look OK? If not, find the error. Your measurement points should lie on a line that gradually decay in a smooth way (within statistical uncertainty). 
  
-Alternative procedure: Select the relevant spectrum region with the photo-peaks and only use the integrals under this (double-)peak for analyzing the data.+==== Deconvoluting the Decay Curve ====
  
-\\ +Notice: The steps indicated below is not very detailedWe assume that you have a teacher physically present that can help you use whatever software and method he/she has prepared for this exerciseHow your teaching institution use the data measured with this RoboLab will varyThey might also have provided more detailed description than what is provided below
-\\  +
-__Analyzing a two-component Decay curve__\\ +
-\\  +
-Use a high-quality data plotting and fitting program (e.g. Origin) to analyze the data. The fitting ''must'' take the uncertainty into account (do not use Excel), otherwise you will get the wrong result. +
-Notice that you always shall use the 1/3 of the time into each measurement as the "middle time point". This is due to decay - after 1/3 of the time you will have equally many counts before and after the 1/3 point (i.e. it is the "middle point"+
-  -For each data point calculate the net count (gross count - background count), the uncertainty of the net count (based on uncertainty of both the gross count and the background count)You might want to use e.g. MS Excel or similar for doing this. +
-  -Enter your data in table ("worksheet" in Origin jargon): Include measurement time (relative to end of irradiation) as x-value, the net count as y-value, and the uncertainty as y-error. +
-  -Plot the data - does it look OK? +
-\\ +
  
 //Manual Method//\\ //Manual Method//\\
Line 137: Line 108:
  
 //Automated Method//\\ //Automated Method//\\
-Use the Origin data-fitting functionality to determine the measured half-life of both components simultaneously. +Use your plotting programs fitting functionality to determine the measured half-life of both decay components simultaneously. It is also possible to fit the background level automatically. If so, it should not deviate much from the background you measured (this typically happen if you have terminated your decay measurement too early)
-"Alternative/Extra": Plot the gross counts instead of the net counts and ask Origin to fit both the background and the two components at the same time. +
 \\  \\ 
  
-__Analyzing the Production Curve of n-activated Ag__\\ +==== Analyzing the Production Curve of n-activated Ag ====
  
-From analyzing the decay curves for the different irradiation times (12, 24, 48, 72, and 144 s) you should have five R<sub>0</sub> values for each of the isotopes:+From analyzing the decay curves for the different irradiation times (e.g. 12, 24, 48, 72, and 144 s) you should have a corresponding number of R<sub>0</sub> values for each of the isotopes:
  
-  -Plot the R<sub>0</sub> values as a function of irradiation time (use Origin or similar software). +  Plot the R<sub>0</sub> values as a function of irradiation time (use Origin or similar software). 
-  -Assume that the R<sub>0</sub> for the <sup>110</sup>Ag irradiation is exact. Use this value to determine the product of the detector-efficiency and neutron flux. In the following, use this value as "true" whenever you need the product. +  Assume that the R<sub>0</sub> for the <sup>110</sup>Ag irradiation is exact. Use this value to determine the product of the detector-efficiency and neutron flux. In the following, use this value as "true" whenever you need the product. 
-  -Use the weight of the silver plate to determine the number of target atoms (silver atoms). +  Use the weight of the silver plate to determine the number of target atoms (silver atoms). 
-  -Now calculate the ''theoretical'' points for the nine other R<sub>0</sub> points. +  Now calculate the ''theoretical'' points for the nine other R<sub>0</sub> points. 
-  -How does your theoretical and experimentally measured points agree? +  How does your theoretical and experimentally measured points agree?
- +
-\\ +
  
 +Notice: Again, the above description is not very detailed. Your teacher will instruct how your are supposed to do this for your particular exercise with the RoboLab system. 
  
-==== Questions for the students ==== 
-Use the cross-sections from the nuclear chart, the half life and a thermal neutron-flux of 2*103 n/cm<sup>2</sup>s to estimate the relative amount you will produce for a 144 s irradiation. Which nuclei will be dominant? 
-Determine what kind of gamma radiation to expect from the silver isotopes produced in the irradiation and their associated relative intensity (e.g. from Berkeley/Lund database). 
  
remote_control_experiments/neutron_activation_of_ag.1696321162.txt.gz · Last modified: 2023-10-03 10:19 by Jon Peter Omtvedt

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