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  proton-capture on 118Te, Page 16 of 29  Not logged in ELOG logo
ID Date Author Category Subject Year
  Draft   Tue Apr 21 22:25:00 2020 JanAnalysis  
  274   Wed Apr 8 23:02:24 2020 LaszloGenerallmd to measurement pairing list 
I use the following list of lmd files combined to a single root file for each measurement.
It is very important to highlight that sometimes the trigger==1 data got corrupted,massive number of trigger==2 like events appear on the detector as trigger==1 signal, because the gas jet target didn't switch off after its normal phase (gas jet remains ON during injection. Maybe some gas jet issue, maybe some bug in the pattern :/ ). To correct for this, one has to cut out these parts from the data. I did these cut outs by hand while looking at the event number vs I_ESR & density gas jet plot (see below). Probably this can be done also in a more automatized way, but I think this is not necessary. In the "124Xe with Scraper" data set it is only 1 time like this, in the 118Te data set 3 times. The other data sets seem fine to me.


-124Xe with scraper:
run090_0001.lmd run091_0001.lmd run092_0001.lmd run094_0001.lmd run095_0001.lmd run096_0001.lmd run098_0001.lmd run099_0001.lmd
if(!(i>1634880 && i<1652240)){do analysis} - (this if condition is valid only if one combines the lmd in numerical order)
(2. Xray calibration parameters)

-124Xe without scraper:

run100_0001.lmd run101_0001.lmd run102_0001.lmd run104_0001.lmd
if(true){do analysis}
(2. Xray calibration parameters)

-118Te with scraper:
run051_0001.lmd run053_0001.lmd run055_0001.lmd run057_0001.lmd run059_0001.lmd run064_0001.lmd run066_0001.lmd
run052_0001.lmd run054_0001.lmd run056_0001.lmd run058_0001.lmd run060_0001.lmd run065_0001.lmd run067_0001.lmd
Changing Xray cables!
run068_0001.lmd run070_0001.lmd run072_0001.lmd run074_0001.lmd run076_0001.lmd run078_0001.lmd run080_0001.lmd run082_0001.lmd run084_0001.lmd run086_0001.lmd
run069_0001.lmd run071_0001.lmd run073_0001.lmd run075_0001.lmd run077_0001.lmd run079_0001.lmd run081_0001.lmd run083_0001.lmd run085_0001.lmd run087_0001.lmd

For Xray analysis:
1. dataset:
Xray[2] = 90 degree Xray[1]=145degree. The timing is switched:
if(!(i>1801830 && i<1807810) && !(i>2348370 && i<2355110)){
if(t_Xray[2]>0) Xray[1] ->Fill();
if(t_Xray[1]>0) Xray[2] ->Fill();
}
(1. Xray calibration parameters --> invalid!)
2. dataset:
if(!(i>5488450-2507171 && i<6125720-2507171)){do analysis}
(2. Xray calibration parameters)

For Si analysis:
if(trigger==1 && !(i>1801830 && i<1807810) && !(i>2348370 && i<2355110) && !(i>5488450 && i<6125720) ){do analysis}
(1. Xray calibration parameters)

-124Xe with scraper - low rate measurement
run046_0001.lmd run047_0001.lmd run047_0003.lmd run048_0002.lmd run049_0002.lmd run050_0001.lmd
run046_0002.lmd run047_0002.lmd run048_0001.lmd run049_0001.lmd run049_0003.lmd run050_0002.lmd
if(true){do analysis}
(1. Xray calibration parameters --> invalid!)


Regarding the gain matching, I assumed that the same 2*16 factors can be used for all data sets, since we didn't change bias voltage (the current remained roughly also the same) and also the detector didn't get any serious radiation damage (this needs to be confirmed!).
A more detailed anaylsis will come on the gain matching after the Easter holiday.

Attachment 1: gas_jet_mailfunction.png
gas_jet_mailfunction.png
  273   Wed Apr 8 20:06:10 2020 LaszloCalibrationCounts in the K-REC peaks 
3 datasets were investigated:
-124Xe with Scraper (2. Xray calibration parameters needed)
-124Xe without Scraper (2. Xray calibration parameters needed)
-118Te with Scraper (1. Xray calibration parameters needed)

I looked all the 35°, 90° and 145° detector spectra:
-For both Xe measurements all 3 detector signal can be evaluated
-For Te beam one can see only in the 145° detector spectra the Kalpha and K-REC peaks (with high uncertainty). For the 35° probably the detector was simply not sensitive enough for such low beam intensities. For the 90° case, I am much surprised, the peaks supposed to be there the most prominent of all. In the spectra, I maybe can recognize a peak at ~27,8keV, but this is even in best case only the Kalpha peak. At the range of the expected K-REC (~40keV), there is a bit of increase in the background overlying the peak. This background increase is also in the background spectra. Also probably this twisted cables issue between 90° and 145° didn't help much. I think anyhow, that maybe this must have some noise related origin. I can remember that the cables (despite all of our and Uwe's tries) were not well grounded, the noise level was kind of floating.

In general, I would also remark that we can see some peaks >60keV in the background, but these luckily don't disturb us.


To evaluate the Xray spectra I used the following algorithm:
1, for each type of beams I used the list of event numbers in the next entry (to exclude "bad" events)
To get the Kalpha and K-REC and other peaks I used the condition trigger==1 (jet ON)
To get the background spectra, I used trigger==2 (Jet OFF). The background spectra is only used to see that there is no underlying peak structure below K-REC. To subtract count, the background histo was NOT in use.
2, While using a well-suiting number of bins, I plot the JetON and JetOFF histos.
By eye I choose the range of the K-REC peak and the range for the background fit on the JetON histo. Ofc range_bckgnd > range_peak.
Simultaneously, I check on the JetOFF histo that both, in the fit-range and in the peak-range, there should not be any peak structure visible.
3, For the fit-range in JetON histo, excluding the peak-range, I fit a linear function, m*x+b. For each bin in the fit-range I subtract m*bin_center+b value from the bin content. After the subtraction I check if I got spectra looking like a single peak sitting on a zero
line.
4, To get the K-REC counts, I sum together all the bin values for each bin of the subtracted histo within the peak-range. For the error calculation, I use Gaussian error prop. The uncertainty of the JetON histo counts = sqrt(counts). Also for the subtraction I make the
error like delta(m*bin_center+b)= sqrt(m*bin_center+b) instead using the uncertainty of the fit parameters. This second one wont make much sense, since the slope of the linear fit is usually close to 0 --> the errors grow unrealistically big.


Based on the algorithm above I got the following counts:
-124Xe with Scraper:
35°: 174 +/- 15
90°: 21299 +/- 150
145°: 2104 +/- 52

-124Xe without Scraper:
35°: 65 +/- 9
90°: 7792 +/- 91
145°: 728 +/- 31

-118Te_part1 with Scraper:
35°: -
90°: 427 +/- 40
145°: -

-118Te_part2 with Scraper:
35°: -
90°: 741 +/- 48
145°: -

-124Xe_lowRate with Scraper:
35°: -
90°: 2121 +/- 52
145°: -
Attachment 1: 124Xe_wScraper_full_spectra_labels_thick.png
124Xe_wScraper_full_spectra_labels_thick.png
Attachment 2: 124Xe_wScraper_90_backgnd.png
124Xe_wScraper_90_backgnd.png
Attachment 3: KREC-pics.zip
  272   Mon Apr 6 23:00:51 2020 LaszloCalibrationbeam energies for 124Xe and 118Te measurements 
"The e- cooler settings were the same for the 124Xe and 118Te beams" - Sergey --> speed of the ions is the same --> same MeV/u

E_beam = 10.0606MeV/u

The uncertainty on the cooloer values should be asked from Markus/Regina
Attachment 1: SP54120040623030.pdf
SP54120040623030.pdf
  271   Mon Apr 6 04:39:19 2020 LaszloCalibration2. Xray energy calibration 
30angle:  E[keV] = 0.015898 *ch-1.91
90angle:  E[keV] = 0.0211075*ch-2.39
145angle: E[keV] = 0.01663  *ch-1.758
Attachment 1: 30angle_Xray_second_calibration.png
30angle_Xray_second_calibration.png
Attachment 2: 90angle_Xray_second_calibration.png
90angle_Xray_second_calibration.png
Attachment 3: 145angle_Xray_second_calibration.png
145angle_Xray_second_calibration.png
Attachment 4: Am_Ba.cal
#gaus fit, gaus fit error, literature (nndc), literature error
#literature used:
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=241AM&unc=nds
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=133BA&unc=nds
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=210PB&unc=nds
#where there is no error given, I put +/-.5 to the last digit
1.77780e+03 8.30485e-02 26.3446 0.0002
3.86555e+03 2.20759e-02 59.5409 0.0001
2.06701e+03 1.25971e-01 30.973 0.0005
2.32011e+03 8.82876e-02 34.987 0.0005
2.37424e+03 2.01021e-01 35.818 0.0005
3.46400e+03 2.53619e-01 53.1622 0.0006
5.12992e+03 2.64070e-01 79.6142 0.0012
5.21686e+03 6.55175e-02 80.9979 0.0011
Attachment 5: Am_Ba.cal
#gaus fit, gaus fit error, literature (nndc), literature error
#literature used:
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=241AM&unc=nds
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=133BA&unc=nds
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=210PB&unc=nds
#where there is no error given, I put +/-.5 to the last digit
1.36175e+03 9.00555e-02 26.3446 0.0002
2.16961e+03 8.05264e-01 43.420 0.003
2.93441e+03 2.14830e-02 59.5409 0.0001
1.57547e+03 4.20575e-02 30.973 0.0005
1.77077e+03 1.39155e-01 34.987 0.0005
2.63200e+03 2.99411e-01 53.1622 0.0006
3.95276e+03 6.39294e-02 80.9979 0.0011
1.36182e+03 1.02182e-01 26.3446 0.0002
2.17086e+03 9.05336e-01 43.420 0.003
2.93383e+03 2.43152e-02 59.5409 0.0001
2.31714e+03 3.80548e-01 46.539 0.001
Attachment 6: 145_det_2calib_Am_Ba.cal
#gaus fit, gaus fit error, literature (nndc), literature error
#literature used:
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=241AM&unc=nds
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=133BA&unc=nds
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=210PB&unc=nds
#where there is no error given, I put +/-.5 to the last digit
1.69027e+03 2.31158e-01 26.3446 0.0002
3.68596e+03 5.13163e-02 59.5409 0.0001
1.95922e+03   6.96080e-02 30.973 0.0005
2.21589e+03 1.68384e-01 34.987 0.0005
3.30072e+03 5.68458e-01 53.1622 0.0006
4.97302e+03 1.24941e-01 80.9979 0.0011
Attachment 7: run115_133Ba_high_30.svg
run115_133Ba_high_30.svg
Attachment 8: run111_241Am_90.svg
run111_241Am_90.svg
Attachment 9: run115_210Pb_90.svg
run115_210Pb_90.svg
  270   Sun Apr 5 20:34:42 2020 LaszloCalibrationXray energies - 1. calibration 
30angle:  E[keV] = 0.0158507 *ch-2.07456
90angle:  E[keV] = 0.01950*ch-2.76
145angle: E[keV] = 0.017988  *ch-1.809

I could identify 2 peaks in the 241Am spectra and 4 peaks in the 133Ba. These peaks are fitted with a gaussian to get their position --> linear energy calibration for the combined (Am+Ba) data sets for each detector. The function I used: E(ch) [keV] = m*ch+b
Attachment 1: 90angle_Xray_first_calibration.png
90angle_Xray_first_calibration.png
Attachment 2: 30angle_Xray_first_calibration.png
30angle_Xray_first_calibration.png
Attachment 3: 145angle_Xray_first_calibration.png
145angle_Xray_first_calibration.png
Attachment 4: 90_det_calib_Am_Ba.cal
#gaus fit, gaus fit error, literature (nndc), literature error
#literature used:
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=241AM&unc=nds
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=133BA&unc=nds
#where there is no error given, I put +/-.5 to the last digit
1493.31 0.26 26.3446 0.0002
3194.81 0.053 59.5409 0.0001
1721.92 0.0574 30.973 0.0005
1937.28 0.163 34.987 0.0005
2864.67 0.443 53.1622 0.0006
4292.25 0.122 80.9979 0.0011

Attachment 5: 30_det_calib_Am_Ba.cal
#gaus fit, gaus fit error, literature (nndc), literature error
#literature used:
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=241AM&unc=nds
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=133BA&unc=nds
#where there is no error given, I put +/-.5 to the last digit
1.79319e+03 3.88460e-01 26.3446 0.0002
3.88726e+03 1.00448e-01 59.5409 0.0001
2.08381e+03 5.25334e-02 30.973 0.0005
2.33719e+03 3.17859e-02 34.987 0.0005
3.48482e+03 1.03952e-01 53.1622 0.0006
5.24059e+03 2.54968e-02 80.9979 0.0011

Attachment 6: 145_det_calib_Am_Ba.cal
#gaus fit, gaus fit error, literature (nndc), literature error
#literature used:
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=241AM&unc=nds
#https://www.nndc.bnl.gov/nudat2/decaysearchdirect.jsp?nuc=133BA&unc=nds
#where there is no error given, I put +/-.5 to the last digit
1.56549e+03 1.83848e-01 26.3446 0.0002
3.41036e+03 4.20525e-02 59.5409 0.0001
1.81904e+03 3.15736e-02 30.973 0.0005
2.04758e+03 8.68290e-02 34.987 0.0005
3.06014e+03 1.98896e-01 53.1622 0.0006
4.61345e+03 5.23412e-02 80.9979 0.0011

Attachment 7: run041_133Ba_high_90.svg
run041_133Ba_high_90.svg
Attachment 8: run040_241Am_90.svg
run040_241Am_90.svg
  269   Thu Mar 26 12:05:22 2020 LaszloCalibrationmeasurement of collimators 
The measurements were taken by using a caliper ruler, with precision of +/-0.05mm
Attachment 1: SP54120032612091.pdf
SP54120032612091.pdf
Attachment 2: SP54120032612090.pdf
SP54120032612090.pdf
  268   Wed Mar 25 15:06:09 2020 LaszloAnalysisquick summary of the run numbers 
Attachment 1: SP54120032515060.pdf
SP54120032515060.pdf
  267   Wed Mar 25 14:26:22 2020 LaszloCalibrationrun111 - Xray90 calib Am241, distance 167.5mm - LESS NOISE 
Detector: 90
Source: 241Am
Distance: 167.5mm
.Start time: ? 23.03.2020
Stop time:  

file name: run111_xxxx.lmd
avrg. rate: 444Hz
dead-time:  5%

Uwe reduced the noise on the 90 degree detector (see elog entry)
  266   Tue Mar 24 10:59:18 2020 JanCalibrationSources - Specifications 
We used the following sources:

Am241 (OM666) [GSI - Uwe]
Reference Activity: 430 kBq
Uncertainty: 3%
Reference Date: 19.09.2006

Ba133 hi (AN-5868) [GSI - Kozuharov]
Reference Activity: 438 kBq
Uncertainty: 3%
Reference Date: 01.06.2019

Ba133 low (OL 918) [GSI - Angela]
Reference Activity: 39.7 kBq
Uncertainty: 3%
Reference Date: 08.09.2006

Pb210 (2015-1552) [GUF - Rene]
Reference Activity: 7.42 (15) kBq
Uncertainty: 0.15/7.42 = 2%
Reference Date: 01.01.2016
Attachment 1: Pb-210-1.pdf
Pb-210-1.pdf Pb-210-1.pdf Pb-210-1.pdf
Attachment 2: 241Am_Uwe.pdf
241Am_Uwe.pdf 241Am_Uwe.pdf 241Am_Uwe.pdf 241Am_Uwe.pdf 241Am_Uwe.pdf 241Am_Uwe.pdf 241Am_Uwe.pdf 241Am_Uwe.pdf
Attachment 3: 133Ba_low.pdf
133Ba_low.pdf 133Ba_low.pdf 133Ba_low.pdf 133Ba_low.pdf 133Ba_low.pdf 133Ba_low.pdf 133Ba_low.pdf 133Ba_low.pdf
Attachment 4: 133Ba_hi.pdf
133Ba_hi.pdf 133Ba_hi.pdf 133Ba_hi.pdf 133Ba_hi.pdf 133Ba_hi.pdf
  265   Tue Mar 24 10:20:26 2020 LaszloCalibrationPictures of the xray calibration 
Attachment 1: IMG_20200324_101357.jpg
IMG_20200324_101357.jpg
Attachment 2: IMG_20200324_101303.jpg
IMG_20200324_101303.jpg
Attachment 3: IMG_20200324_101334.jpg
IMG_20200324_101334.jpg
Attachment 4: IMG_20200324_100725.jpg
IMG_20200324_100725.jpg
  264   Tue Mar 24 00:11:35 2020 LaszloCalibrationrun116 - Xray35 calib AM241, distance 334mm 
Detector: 35
Source: 241Am
Distance: 334mm
Start time: 00:11:03 24.03.2020
Stop time:  10:01:4224.03.2020

file name: run116_xxxx.lmd
avrg. rate: 20Hz
dead-time:  0%
  263   Mon Mar 23 22:25:41 2020 LaszloCalibrationrun115 - Xray35 Ba133 d=334mm, Xray90 Lead source, d=167.5mm 
Simultaneous measurement of Xray35 and Xray90. The dead-time is <3%

Detector: 35
Source: 133Ba - strong source
Distance: 334mm

Detector: 90
Source: Lead source
Distance: 167.5mm: the lead source was measured 3mm width with the source in the middle. Therefore, I set the paper zylinder to ~169mm distance. 

Start time: 22:25:22 23.03.2020
Stop time:  00:04:49 24.03.2020

file name: run115_xxxx.lmd
avrg. rate35: 75Hz
avrg. rate90: 55Hz
dead-time:  2%

Uwe reduced the noise on the 145 degree detector as well. 

During measurement the oscilloscope remained connected!
  262   Mon Mar 23 21:47:40 2020 LaszloCalibrationrun114 - Xray145 calib Ba133, distance 305mm - LESS NOISE 
Detector: 145
Source: 133Ba - strong source
Distance: 305mm
Start time: 21:47:20 23.03.2020
Stop time:  22:04:06 23.03.2020

file name: run114_xxxx.lmd
avrg. rate: 950Hz
dead-time:  11%

Uwe reduced the noise on the 145 degree detector as well. 

During measurement the oscilloscope remained connected!
  261   Mon Mar 23 20:52:37 2020 LaszloCalibrationrun113 - Xray145 calib Am241, distance 305mm - LESS NOISE 
Detector: 145
Source: 241Am
Distance: 305mm
Start time: 20:01:43 23.03.2020
Stop time:  21:43:34

file name: run113_xxxx.lmd
avrg. rate: 220Hz
dead-time:  2.5%

Uwe reduced the noise on the 145 degree detector as well. 
  260   Mon Mar 23 19:32:53 2020 LaszloCalibrationrun112 - Xray90 calib Am241, distance 200mm - LESS NOISE 
Detector: 90
Source: 241Am
Distance: 200mm
Start time: 20:01:43 23.03.2020
Stop time:  

file name: run112_xxxx.lmd
avrg. rate: 444Hz
dead-time:  5%

Uwe reduced the noise on the 90 degree detector (see elog entry)
  259   Mon Mar 23 18:17:27 2020 LaszloCalibrationrun110 - Xray90 calib Ba133, distance 167.5mm -low rate - LESS NOISE 
Detector: 90
Source: Ba133 - weak source
Distance: 167.5mm
Start time: 18:14:50 23.03.2020
Stop time:  

file name: run110_xxxx.lmd
avrg. rate: 160Hz
dead-time:  2%

Uwe reduced the noise on the 90 degree detector (see previous elog entry)
  258   Mon Mar 23 18:15:55 2020 LaszloGeneralnoisy 90degree Xray det 
Uwe found out, that there was some common ground effect between 90 and 145 degree detectors. after moving the grounds, we could record much more nicer (Gaus 
shaped) peaks in the spectra. Now we continue with this settings
  257   Mon Mar 23 17:40:33 2020 LaszloCalibrationrun109 - Xray90 calib Ba133, distance 167.5mm -low rate 
Detector: 90
Source: Ba133 - weak source
Distance: 167.5mm
Start time: 17:40:11 23.03.2020
Stop time:  

file name: run109_xxxx.lmd
avrg. rate: 170Hz
dead-time:  2%
  256   Mon Mar 23 17:32:42 2020 LaszloCalibrationrun108 - Xray90 calib Ba133, distance 167.5mm - high rate - deadtime too high! 
Detector: 90
Source: Ba133 - strong source
Distance: 167.5mm
Start time: 17:32:11 23.03.2020
Stop time:  17:35:34

file name: run108_xxxx.lmd
avrg. rate: 2.7kHz
dead-time:  26%
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