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ID Date Author Category Subject Yeardown
  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
  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
  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
  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
  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
  Draft   Tue Apr 21 22:25:00 2020 JanAnalysis  
  277   Thu Apr 23 19:09:58 2020 LaszloCalibrationtheoretical K-REC cross sections  
Find attached Andrey Surzhykov's calculations for the theta angle in respect to the beam direction (in lab. frame) vs. cross section for 124Xe54+ and 118Te52+.
The calculations made for collision with two H atoms with the accuracy of 1%. There are no molecular corrections done, but these corrections are within 1%.

The photon-emission is symmetrical in the azimuthal phi angle, but asymetric in theta. The K-REC cross section is given for each integer theta angle. The problem is that our 90° and 145° xray detectors cover more integer theta-angles --> The disk shaped entrance window of the Xray-detectors is sliced for each covered theta angles, and the CS values are averaged together with the weights of the area of the corresponding slice. The 35° det had a non-disk shaped slit collimator! Was it aligned vertical or horizontal or random? I assumed that it had a vertical position --> only cs at theta=35° needs to taken into account

90°145°35°
weighted cs_Xe [barn/sr]128,44441,96745,550
weighted cs_Te [barn/sr]118,61638,91841,740


For the steradian values I calculated the area of the entrance window of the Xray detectors and I divided it with the area of the sphere with radius = distance between source and det. If r=radius of the entrance window, D=distance between source and det.: covered steradian = r^2*pi/(4*pi*D^2) [%], covered steradian = 4Pi*[r^2*pi/(4*pi*D^2)] [4pi]. This is valid for the 90° and 145° Xray detectors. The area of 35° det. was calculated individually.

90°145°35°
sr [%]0,002370,000760,00002
sr [4pi]0,02980,00960,00030


I converted barn/sr to barn in the following way: steradian[4pi]*weigthed_cs [barn/sr] = weigthed_cs [barn]. I am not 100% sure if I need here the steradian in [4pi] or in [%].

90°145°35°
weighted cs_Xe [barn]3,82470,40120,0137
weighted cs_Te [barn]3,53210,37200,0125
Attachment 1: CS_theory_all.png
CS_theory_all.png
Attachment 2: CS_theory_all.ps
CS_theory_all.ps
Attachment 3: CS_theory_90Xe.png
CS_theory_90Xe.png
Attachment 4: CS_theory_90Xe.ps
CS_theory_90Xe.ps
Attachment 5: CS_theory_90Te.png
CS_theory_90Te.png
Attachment 6: CS_theory_90Te.ps
CS_theory_90Te.ps
Attachment 7: DCS_Z_54_Tp_10MeV.dat
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1. 0.9184409606576515
2. 1.0443879628122903
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36. 47.75198878403283
37. 49.97446153088989
38. 52.21496883482496
39.00000000000001 54.470586171241614
40. 56.7383773551312
41. 59.01539859855422
42. 61.29870254528142
43.00000000000001 63.58534227653866
44. 65.87237528199884
45. 68.15686739036538
46. 70.43589665410244
47.00000000000001 72.70655718308338
48. 74.96596292214365
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50. 79.43958721922418
51. 81.64816596016036
52. 83.83421736595126
53. 85.99500893349557
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55.00000000000001 90.23009115346127
56. 92.29913511346422
57. 94.33243210949429
58.00000000000001 96.32748672373847
59. 98.28186001390355
60. 100.19317230761206
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63.00000000000001 105.64589136814853
64. 107.36244043326852
65.00000000000001 109.0250098024874
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75.00000000000001 122.28716473903538
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78.00000000000001 124.93823772099097
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80. 126.33683275148397
81. 126.9231748161348
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83.00000000000001 127.86701099212635
84. 128.223610405669
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87. 128.82872935716867
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101. 122.56285609918638
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104. 119.38174987359533
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106. 116.93550778989012
107. 115.61920579776323
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109. 112.80838464475747
110.00000000000001 111.31732059842409
111. 109.77156222750445
112. 108.17299063302771
113. 106.52354426597255
114. 104.82521658415874
114.99999999999999 103.08005365911461
116.00000000000001 101.29015173546108
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118. 97.58475178082271
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120. 93.72669465271724
121.00000000000001 91.746121182048
122. 89.73429781347248
123.00000000000001 87.69360022591539
124. 85.62643335241032
125. 83.53522863152084
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127.00000000000003 79.29054729738027
128. 77.14204108168238
129. 74.97943219846945
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131. 70.62200458781662
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133. 66.23854061062511
134.00000000000003 64.04340133356263
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140. 50.984565571903104
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142. 46.73446324299586
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146.00000000000003 38.50602236427895
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149. 32.64642236702124
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153. 25.363649146012833
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162. 11.81411736919071
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165. 8.335915447699179
166.00000000000003 7.30445168388348
166.99999999999997 6.338963713551622
168. 5.440544225441671
169. 4.610209744476686
170. 3.848899540058887
171. 3.157474617532845
172.00000000000003 2.536716793847944
173. 1.9873278583654939
174. 1.5099288196705962
175.00000000000003 1.1050592391610732
176. 0.7731766520971258
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178.00000000000003 0.32978961186464684
179. 0.21878612371563544
180. 0.1817710216397566
Attachment 8: DCS_Z_52_Tp_10MeV.dat
0. 0.6838809884595187
1. 0.7224229853331035
2. 0.8379964473235315
3. 1.030443872137824
4. 1.2995030344282912
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6. 2.065886722645698
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15. 9.13777448057661
16. 10.268659287456684
17. 11.463627137414845
18. 12.721065962577109
19. 14.039281545545448
20. 15.416500129385255
21. 16.850871139764088
22. 18.340470013614155
23. 19.88330112852013
24. 21.477300826887046
25. 23.12034052881444
26. 24.81022992749396
27. 26.54472026085621
28. 28.321507653123813
29.000000000000004 30.138236519876482
30. 31.99250303019941
31. 33.88185861947699
32. 35.803813546395155
33. 37.75584048773818
34. 39.73537816460896
35. 41.73983499375132
36. 43.76659275772978
37. 45.81301028780408
38. 47.87642715343563
39.00000000000001 49.954167352475665
40. 52.043542996208096
41. 54.14185798355203
42. 56.24641165887502
43.00000000000001 58.35450244801732
44. 60.46343146728837
45. 62.5705061003606
46. 64.67304353815759
47.00000000000001 66.76837427700832
48. 68.85384557051732
49. 70.92682483078326
50. 72.98470297478
51. 75.02489771189985
52. 77.0448567688431
53. 79.0420610482222
54. 81.01402771743378
55.00000000000001 82.95831322453394
56. 84.87251623803525
57. 86.75428050772088
58.00000000000001 88.6012976437524
59. 90.4113098115192
60. 92.18211233985382
61. 93.91155624040339
62. 95.59755063611817
63.00000000000001 97.23806509697859
64. 98.8311318812456
65.00000000000001 100.37484808067475
66. 101.86737766828935
67.00000000000001 103.30695344745868
68. 104.69187890117422
69.00000000000001 106.02052994056153
70. 107.29135655180244
71. 108.5028843407837
72. 109.65371597491449
73.00000000000001 110.74253252168937
74. 111.76809468369437
75.00000000000001 112.72924392987584
76. 113.62490352300958
77. 114.454079443417
78.00000000000001 115.21586120908894
79. 115.90942259247545
80. 116.53402223430722
81. 117.08900415490466
82. 117.57379816352693
83.00000000000001 117.98792016639949
84. 118.33097237414394
85. 118.60264340941445
86.00000000000001 118.80270831562267
87. 118.93102846770623
88. 118.98755138596732
89.00000000000001 118.97231045407382
90. 118.88542454238262
91. 118.72709753780394
92. 118.49761778148746
93.00000000000001 118.1973574156676
94.00000000000001 117.8267716410606
95. 117.38639788626082
96. 116.87685489063509
97. 116.29884170226605
98. 115.65313659254451
99.00000000000001 114.9405958890601
100. 114.16215272848856
101. 113.3188157312197
102. 112.41166759952044
103. 111.44186364106933
104. 110.41063021974982
105.00000000000001 109.31926313563206
106. 108.16912593611966
107. 106.96164816028295
108. 105.69832351844508
109. 104.3807080091302
110.00000000000001 103.01041797552814
111. 101.58912810367194
112. 100.11856936456695
113. 98.60052690255144
114. 97.03683787220862
114.99999999999999 95.42938922619064
116.00000000000001 93.78011545634986
117. 92.0909962906127
118. 90.36405434806198
119. 88.60135275473215
120. 86.80499272264713
121.00000000000001 84.97711109466407
122. 83.1198778577115
123.00000000000001 81.23549362703562
124. 79.32618710409213
125. 77.39421251073887
126.00000000000001 75.44184700240568
127.00000000000003 73.47138806293053
128. 71.48515088376489
129. 69.4854657302612
130.00000000000003 67.47467529776368
131. 65.45513206022716
132. 63.429195614092336
133. 61.3992300201446
134.00000000000003 59.36760114608176
135. 57.33667401250889
136. 55.308810145072414
137. 53.28636493543301
138.00000000000003 51.27168501376619
139. 49.26710563546159
140. 47.27494808467541
141. 45.29751709737059
142. 43.337098306456504
143. 41.39595571161337
144. 39.476329176362796
145.00000000000003 37.580431954915426
146.00000000000003 35.71044825129239
147. 33.86853081318914
148. 32.056798563011185
149. 30.277334268472416
150.00000000000003 28.532182255112247
151. 26.82334616304045
152. 25.152786750176944
153. 23.522419744211014
154. 21.934113745450986
155. 20.389688182690108
156.00000000000003 18.890911324162325
157. 17.43949834560509
158. 16.037109457394024
159. 14.685348092655238
160. 13.385759158201713
161.00000000000003 12.139827350079225
162. 10.948975535442912
163. 9.81456320242211
164. 8.737884979563095
165. 7.720169226369559
166.00000000000003 6.762576696392841
166.99999999999997 5.866199274248659
168. 5.032058787863961
169. 4.261105897183412
170. 3.554219060485478
171. 2.9122035793804977
172.00000000000003 2.335790723483083
173. 1.8256369356687627
174. 1.382323118743823
175.00000000000003 1.0063540042709131
176. 0.6981576042097696
176.99999999999997 0.45808474594681375
178.00000000000003 0.28640869119862783
179. 0.18332483918885642
180. 0.14895051440953486
Attachment 9: source_vs_XrayDet_sketch.pdf
source_vs_XrayDet_sketch.pdf
  278   Wed Apr 29 16:06:28 2020 LaszloCalibrationefficiency fit - 90degree, combined dataset 
For the efficiency vs E fit of the 90degree Xray detector I have used the following phenomenological funciton:

f(x) = a * (1-exp(-(x-c)/b)) * exp(-x/d)

Here the first exponent member is a saturation curve. This part describes the passing through of the two Be windows (chamber + before detector) and through the dead layer of Ge crystal. One needs a minimum energy to enter to the detecting Ge crystal = C parameter. b parameter = characteristic absorbtion E of these nondetecting layers.
The second exponent is an exponential decrease of the detector efficiency. Photons with higher energy are less detectable by the germaniums. The d parameter is the characteristic E for hard Xray and gamma (>40keV) detectability. 

https://www.amptek.com/internal-products/si-pin-vs-cdte-comparison

//Jan's comment: the tail of this function should more or less follow a linear trend a bit above than 40 keV.


In the attachment there is an example fit for 90 degree with combined 1. and 2. (before and after beamtime) calibration datasets. 
I made the fit with gnuplot:

degrees of freedom    (FIT_NDF)                        : 8
rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 0.419915
variance of residuals (reduced chisquare) = WSSR/ndf   : 0.176329
p-value of the Chisq distribution (FIT_P)              : 0.994094

Final set of parameters            Asymptotic Standard Error
=======================            ==========================
a               = 0.00308376       +/- 0.0005144    (16.68%)
c               = 15.6259          +/- 2.035        (13.03%)
b               = 9.36888          +/- 3.16         (33.73%)
d               = 177.141          +/- 84.95        (47.95%)

Laszlo's out.
Attachment 1: efficiency_90degree-1an2datasets_phen_lin.png
efficiency_90degree-1an2datasets_phen_lin.png
Attachment 2: efficiency_90degree-1an2datasets_phen_lin_bigRange.png
efficiency_90degree-1an2datasets_phen_lin_bigRange.png
  279   Thu Apr 30 17:40:57 2020 LaszloCalibrationefficiency fits 
For all 3 detector the calibration data sets were combined to include the systematics in the fit results directly. Combining means not a weighted average, just simple all data points were included into the fit --> doubled efficiency value for most of the energies.
The g(x) = a * (1-exp(-(x-c)/b)) * exp(-x/d) function was used to describe the behavior of the Germanium detectors for the whole range of energies (global behavior). From these fits the 80keV outlier point was excluded. This is very strange that it doesn't follow the trend, it would be nice to find out why not.
Between 40-75keV a linear fit was carried out as well. This can also approximate quite well this local energy range, what we need for the K-REC peaks.
l(x) = m*x+e

All the fits were done by gnuplot, but it was also confirmed that ROOT gives us the same parameters + errors + chisquare. One just need to choose well the starting values :)


90° fits:
degrees of freedom    (FIT_NDF)                        : 8
rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 0.419915
variance of residuals (reduced chisquare) = WSSR/ndf   : 0.176329
p-value of the Chisq distribution (FIT_P)              : 0.994094

Final set of parameters            Asymptotic Standard Error
=======================            ==========================
a               = 0.00308376       +/- 0.0005144    (16.68%)
c               = 15.6259          +/- 2.035        (13.03%)
b               = 9.36888          +/- 3.16         (33.73%)
d               = 177.141          +/- 84.95        (47.95%)

degrees of freedom    (FIT_NDF)                        : 4
rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 0.283372
variance of residuals (reduced chisquare) = WSSR/ndf   : 0.0802998
p-value of the Chisq distribution (FIT_P)              : 0.988405

Final set of parameters            Asymptotic Standard Error
=======================            ==========================
m               = -6.22672e-06     +/- 1.836e-06    (29.48%)
e               = 0.00256426       +/- 9.873e-05    (3.85%)



145° fits:
degrees of freedom    (FIT_NDF)                        : 6
rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 0.379472
variance of residuals (reduced chisquare) = WSSR/ndf   : 0.143999
p-value of the Chisq distribution (FIT_P)              : 0.990247

Final set of parameters            Asymptotic Standard Error
=======================            ==========================
a               = 0.0012346        +/- 0.0006794    (55.03%)
c               = 11.3754          +/- 4.075        (35.82%)
b               = 15.6961          +/- 13.2         (84.1%)
d               = 116.084          +/- 99.83        (86%)

degrees of freedom    (FIT_NDF)                        : 2
rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 0.327728
variance of residuals (reduced chisquare) = WSSR/ndf   : 0.107405
p-value of the Chisq distribution (FIT_P)              : 0.898161

Final set of parameters            Asymptotic Standard Error
=======================            ==========================
m               = -2.39246e-06     +/- 1.278e-06    (53.42%)
e               = 0.000848859      +/- 7.329e-05    (8.634%)



35° fit:
degrees of freedom    (FIT_NDF)                        : 7
rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 1.40676
variance of residuals (reduced chisquare) = WSSR/ndf   : 1.97896
p-value of the Chisq distribution (FIT_P)              : 0.0538635

Final set of parameters            Asymptotic Standard Error
=======================            ==========================
a               = 0.000114396      +/- 0.0002367    (206.9%)
c               = 14.3178          +/- 8.322        (58.13%)
b               = 16.7454          +/- 43.21        (258%)
d               = 79.7991          +/- 173.2        (217.1%)

degrees of freedom    (FIT_NDF)                        : 3
rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 1.21233
variance of residuals (reduced chisquare) = WSSR/ndf   : 1.46975
p-value of the Chisq distribution (FIT_P)              : 0.220529

Final set of parameters            Asymptotic Standard Error
=======================            ==========================
m               = -3.7879e-07      +/- 3.143e-07    (82.99%)
e               = 7.31447e-05      +/- 1.788e-05    (24.45%)



> For the efficiency vs E fit of the 90degree Xray detector I have used the following phenomenological funciton:
> 
> f(x) = a * (1-exp(-(x-c)/b)) * exp(-x/d)
> 
> Here the first exponent member is a saturation curve. This part describes the passing through of the two Be windows (chamber + before detector) and through the dead layer of Ge crystal. One needs a minimum energy to enter to the detecting Ge crystal = C parameter. b parameter = characteristic absorbtion E of these nondetecting layers.
> The second exponent is an exponential decrease of the detector efficiency. Photons with higher energy are less detectable by the germaniums. The d parameter is the characteristic E for hard Xray and gamma (>40keV) detectability. 
> 
> https://www.amptek.com/internal-products/si-pin-vs-cdte-comparison
> 
> //Jan's comment: the tail of this function should more or less follow a linear trend a bit above than 40 keV.
> 
> 
> In the attachment there is an example fit for 90 degree with combined 1. and 2. (before and after beamtime) calibration datasets. 
> I made the fit with gnuplot:
> 
> degrees of freedom    (FIT_NDF)                        : 8
> rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 0.419915
> variance of residuals (reduced chisquare) = WSSR/ndf   : 0.176329
> p-value of the Chisq distribution (FIT_P)              : 0.994094
> 
> Final set of parameters            Asymptotic Standard Error
> =======================            ==========================
> a               = 0.00308376       +/- 0.0005144    (16.68%)
> c               = 15.6259          +/- 2.035        (13.03%)
> b               = 9.36888          +/- 3.16         (33.73%)
> d               = 177.141          +/- 84.95        (47.95%)
> 
> Laszlo's out.
Attachment 1: 90degree_efficiency.zip
Attachment 2: 145degree_efficiency.zip
Attachment 3: 35degree_efficiency.zip
  280   Thu Apr 30 22:55:45 2020 LaszloCalibrationinverse square law test 
I have made also the inverse square law fits. We have data only for 90degre with the 241Am source, but both for the 1. and 2. calibrations. The 1. and 2. calibration data sets treated separate.
2 peaks were investigated, 59.5keV and 26.3keV, at two distances 184.8mm and 217.3mm. These distances are the sum of 4 distances:
a = width of plastic head. uncert.: +/- 0.05mm, measured with caliper.
b = width of the brass collimator. uncert.: +/- 0.05mm, measured with caliper.
c = width of protector plastic ring. uncert.: +/- 0.05mm, measured with caliper.
d= distance of the paper head. uncert: +/- 0.5mm, judged by the eye :)

The Be window and the dead layer of the Ge detector is not taken into account.

The distances calculated as D=a+b+c+d.

The conclusion is that the uncertainty coming from the distance measurements are negligible compared to the other uncertainties. The data obey the inverse square law.


> For all 3 detector the calibration data sets were combined to include the systematics in the fit results directly. Combining means not a weighted average, just simple all data points were included into the fit --> doubled efficiency value for most of the energies.
> The g(x) = a * (1-exp(-(x-c)/b)) * exp(-x/d) function was used to describe the behavior of the Germanium detectors for the whole range of energies (global behavior). From these fits the 80keV outlier point was excluded. This is very strange that it doesn't follow the trend, it would be nice to find out why not.
> Between 40-75keV a linear fit was carried out as well. This can also approximate quite well this local energy range, what we need for the K-REC peaks.
> l(x) = m*x+e
> 
> All the fits were done by gnuplot, but it was also confirmed that ROOT gives us the same parameters + errors + chisquare. One just need to choose well the starting values :)
> 
> 
> 90° fits:
> degrees of freedom    (FIT_NDF)                        : 8
> rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 0.419915
> variance of residuals (reduced chisquare) = WSSR/ndf   : 0.176329
> p-value of the Chisq distribution (FIT_P)              : 0.994094
> 
> Final set of parameters            Asymptotic Standard Error
> =======================            ==========================
> a               = 0.00308376       +/- 0.0005144    (16.68%)
> c               = 15.6259          +/- 2.035        (13.03%)
> b               = 9.36888          +/- 3.16         (33.73%)
> d               = 177.141          +/- 84.95        (47.95%)
> 
> degrees of freedom    (FIT_NDF)                        : 4
> rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 0.283372
> variance of residuals (reduced chisquare) = WSSR/ndf   : 0.0802998
> p-value of the Chisq distribution (FIT_P)              : 0.988405
> 
> Final set of parameters            Asymptotic Standard Error
> =======================            ==========================
> m               = -6.22672e-06     +/- 1.836e-06    (29.48%)
> e               = 0.00256426       +/- 9.873e-05    (3.85%)
> 
> 
> 
> 145° fits:
> degrees of freedom    (FIT_NDF)                        : 6
> rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 0.379472
> variance of residuals (reduced chisquare) = WSSR/ndf   : 0.143999
> p-value of the Chisq distribution (FIT_P)              : 0.990247
> 
> Final set of parameters            Asymptotic Standard Error
> =======================            ==========================
> a               = 0.0012346        +/- 0.0006794    (55.03%)
> c               = 11.3754          +/- 4.075        (35.82%)
> b               = 15.6961          +/- 13.2         (84.1%)
> d               = 116.084          +/- 99.83        (86%)
> 
> degrees of freedom    (FIT_NDF)                        : 2
> rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 0.327728
> variance of residuals (reduced chisquare) = WSSR/ndf   : 0.107405
> p-value of the Chisq distribution (FIT_P)              : 0.898161
> 
> Final set of parameters            Asymptotic Standard Error
> =======================            ==========================
> m               = -2.39246e-06     +/- 1.278e-06    (53.42%)
> e               = 0.000848859      +/- 7.329e-05    (8.634%)
> 
> 
> 
> 35° fit:
> degrees of freedom    (FIT_NDF)                        : 7
> rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 1.40676
> variance of residuals (reduced chisquare) = WSSR/ndf   : 1.97896
> p-value of the Chisq distribution (FIT_P)              : 0.0538635
> 
> Final set of parameters            Asymptotic Standard Error
> =======================            ==========================
> a               = 0.000114396      +/- 0.0002367    (206.9%)
> c               = 14.3178          +/- 8.322        (58.13%)
> b               = 16.7454          +/- 43.21        (258%)
> d               = 79.7991          +/- 173.2        (217.1%)
> 
> degrees of freedom    (FIT_NDF)                        : 3
> rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 1.21233
> variance of residuals (reduced chisquare) = WSSR/ndf   : 1.46975
> p-value of the Chisq distribution (FIT_P)              : 0.220529
> 
> Final set of parameters            Asymptotic Standard Error
> =======================            ==========================
> m               = -3.7879e-07      +/- 3.143e-07    (82.99%)
> e               = 7.31447e-05      +/- 1.788e-05    (24.45%)
> 
> 
> 
> > For the efficiency vs E fit of the 90degree Xray detector I have used the following phenomenological funciton:
> > 
> > f(x) = a * (1-exp(-(x-c)/b)) * exp(-x/d)
> > 
> > Here the first exponent member is a saturation curve. This part describes the passing through of the two Be windows (chamber + before detector) and through the dead layer of Ge crystal. One needs a minimum energy to enter to the detecting Ge crystal = C parameter. b parameter = characteristic absorbtion E of these nondetecting layers.
> > The second exponent is an exponential decrease of the detector efficiency. Photons with higher energy are less detectable by the germaniums. The d parameter is the characteristic E for hard Xray and gamma (>40keV) detectability. 
> > 
> > https://www.amptek.com/internal-products/si-pin-vs-cdte-comparison
> > 
> > //Jan's comment: the tail of this function should more or less follow a linear trend a bit above than 40 keV.
> > 
> > 
> > In the attachment there is an example fit for 90 degree with combined 1. and 2. (before and after beamtime) calibration datasets. 
> > I made the fit with gnuplot:
> > 
> > degrees of freedom    (FIT_NDF)                        : 8
> > rms of residuals      (FIT_STDFIT) = sqrt(WSSR/ndf)    : 0.419915
> > variance of residuals (reduced chisquare) = WSSR/ndf   : 0.176329
> > p-value of the Chisq distribution (FIT_P)              : 0.994094
> > 
> > Final set of parameters            Asymptotic Standard Error
> > =======================            ==========================
> > a               = 0.00308376       +/- 0.0005144    (16.68%)
> > c               = 15.6259          +/- 2.035        (13.03%)
> > b               = 9.36888          +/- 3.16         (33.73%)
> > d               = 177.141          +/- 84.95        (47.95%)
> > 
> > Laszlo's out.
Attachment 1: inverse_square_law.zip
  281   Wed May 6 23:02:42 2020 LaszloCalibrationefficiency values 
I have calculated the efficiency values by putting the energies of the K-REC peaks into the phenomenological (empirical) function and into the linear function (see below). The K-REC peak's position I got from a Gaussian-fit on the peak. There are 5 data sets in total:
With 1. E-calibration parameters:
-124Xe low rate measurement
-118Te 1. data set (before cable-swap)
With 2. E-calibration parameters:
-118Te 2. data set (after cable-swap)
-124Xe with scraper
-124Xe without scraper

When using the 1. E-calibration parameters, the obtained K-REC energies were much offset (124Xe_lowRate E_KREC=4.00577e+01keV, 118Te_1dataset: E_KREC=3.70922e+01keV), even though I tried all possible linear combinations of the parameters for 90° and 145°. Therefore, at the end I used the theoretical energies of the K-REC peaks from Thomas's website: http://www-ap.gsi.de/Thomas/ap_html_research/energy/index.php
Most probably, the problem is not with the 1. E-calibration itself (the source measurement looks consistent), but with the changing gate width during these measurements. These problematic data sets I marked with a " * " in the tables.

90°:
124Xe_wScraper124Xe_woScraper118Te_wScraper_part1118Te_wScraper_part2124Xe_wScraper_lowRate
K-REC E [keV]4,6093E+014,6116E+01*4,3241E+014,3135E+01*4,6336E+01
g(E_KREC) (phenomenology)0,0022850,002285*0,0022890,002289*0,002284
l(E_KREC) (linear)0,0022770,002277*0,0022950,002296*0,002276
diff. betw. f(E_KREC) and g(E_KREC)0,35%0,35%0,26%0,29%0,38%


145°:
124Xe_wScraper124Xe_woScraper
K-REC E [keV]4,1292E+014,1275E+01
g(E_KREC) (phenomenology)0,0007360,000736
l(E_KREC) (linear)0,0007500,000750
diff. betw. f(E_KREC) and g(E_KREC)1,82%1,83%


35°:
124Xe_wScraper124Xe_woScraper
K-REC E [keV]5,2309E+015,2478E+01
g(E_KREC) (phenomenology)0,00005320,0000532
l(E_KREC) (linear)0,00005330,0000533
diff. betw. f(E_KREC) and g(E_KREC)0,15%0,13%



> I have made also the inverse square law fits. We have data only for 90degre with the 241Am source, but both for the 1. and 2. calibrations. The 1. and 2. calibration data sets treated separate.
> 2 peaks were investigated, 59.5keV and 26.3keV, at two distances 184.8mm and 217.3mm. These distances are the sum of 4 distances:
> a = width of plastic head. uncert.: +/- 0.05mm, measured with caliper.
> b = width of the brass collimator. uncert.: +/- 0.05mm, measured with caliper.
> c = width of protector plastic ring. uncert.: +/- 0.05mm, measured with caliper.
> d= distance of the paper head. uncert: +/- 0.5mm, judged by the eye Smile
>
> The Be window and the dead layer of the Ge detector is not taken into account.
>
> The distances calculated as D=a+b+c+d.
>
> The conclusion is that the uncertainty coming from the distance measurements are negligible compared to the other uncertainties. The data obey the inverse square law.
>
>
> > For all 3 detector the calibration data sets were combined to include the systematics in the fit results directly. Combining means not a weighted average, just simple all data points were included into the fit --> doubled efficiency value for most of the energies.
> > The g(x) = a * (1-exp(-(x-c)/b)) * exp(-x/d) function was used to describe the behavior of the Germanium detectors for the whole range of energies (global behavior). From these fits the 80keV outlier point was excluded. This is very strange that it doesn't follow the trend, it would be nice to find out why not.
> > Between 40-75keV a linear fit was carried out as well. This can also approximate quite well this local energy range, what we need for the K-REC peaks.
> > l(x) = m*x+e
> >
> > All the fits were done by gnuplot, but it was also confirmed that ROOT gives us the same parameters + errors + chisquare. One just need to choose well the starting values Smile
> >
> >
> > 90° fits:
> > degrees of freedom (FIT_NDF) : 8
> > rms of residuals (FIT_STDFIT) = sqrt(WSSR/ndf) : 0.419915
> > variance of residuals (reduced chisquare) = WSSR/ndf : 0.176329
> > p-value of the Chisq distribution (FIT_P) : 0.994094
> >
> > Final set of parameters Asymptotic Standard Error
> > ======================= ==========================
> > a = 0.00308376 +/- 0.0005144 (16.68%)
> > c = 15.6259 +/- 2.035 (13.03%)
> > b = 9.36888 +/- 3.16 (33.73%)
> > d = 177.141 +/- 84.95 (47.95%)
> >
> > degrees of freedom (FIT_NDF) : 4
> > rms of residuals (FIT_STDFIT) = sqrt(WSSR/ndf) : 0.283372
> > variance of residuals (reduced chisquare) = WSSR/ndf : 0.0802998
> > p-value of the Chisq distribution (FIT_P) : 0.988405
> >
> > Final set of parameters Asymptotic Standard Error
> > ======================= ==========================
> > m = -6.22672e-06 +/- 1.836e-06 (29.48%)
> > e = 0.00256426 +/- 9.873e-05 (3.85%)
> >
> >
> >
> > 145° fits:
> > degrees of freedom (FIT_NDF) : 6
> > rms of residuals (FIT_STDFIT) = sqrt(WSSR/ndf) : 0.379472
> > variance of residuals (reduced chisquare) = WSSR/ndf : 0.143999
> > p-value of the Chisq distribution (FIT_P) : 0.990247
> >
> > Final set of parameters Asymptotic Standard Error
> > ======================= ==========================
> > a = 0.0012346 +/- 0.0006794 (55.03%)
> > c = 11.3754 +/- 4.075 (35.82%)
> > b = 15.6961 +/- 13.2 (84.1%)
> > d = 116.084 +/- 99.83 (86%)
> >
> > degrees of freedom (FIT_NDF) : 2
> > rms of residuals (FIT_STDFIT) = sqrt(WSSR/ndf) : 0.327728
> > variance of residuals (reduced chisquare) = WSSR/ndf : 0.107405
> > p-value of the Chisq distribution (FIT_P) : 0.898161
> >
> > Final set of parameters Asymptotic Standard Error
> > ======================= ==========================
> > m = -2.39246e-06 +/- 1.278e-06 (53.42%)
> > e = 0.000848859 +/- 7.329e-05 (8.634%)
> >
> >
> >
> > 35° fit:
> > degrees of freedom (FIT_NDF) : 7
> > rms of residuals (FIT_STDFIT) = sqrt(WSSR/ndf) : 1.40676
> > variance of residuals (reduced chisquare) = WSSR/ndf : 1.97896
> > p-value of the Chisq distribution (FIT_P) : 0.0538635
> >
> > Final set of parameters Asymptotic Standard Error
> > ======================= ==========================
> > a = 0.000114396 +/- 0.0002367 (206.9%)
> > c = 14.3178 +/- 8.322 (58.13%)
> > b = 16.7454 +/- 43.21 (258%)
> > d = 79.7991 +/- 173.2 (217.1%)
> >
> > degrees of freedom (FIT_NDF) : 3
> > rms of residuals (FIT_STDFIT) = sqrt(WSSR/ndf) : 1.21233
> > variance of residuals (reduced chisquare) = WSSR/ndf : 1.46975
> > p-value of the Chisq distribution (FIT_P) : 0.220529
> >
> > Final set of parameters Asymptotic Standard Error
> > ======================= ==========================
> > m = -3.7879e-07 +/- 3.143e-07 (82.99%)
> > e = 7.31447e-05 +/- 1.788e-05 (24.45%)
> >
> >
> >
> > > For the efficiency vs E fit of the 90degree Xray detector I have used the following phenomenological funciton:
> > >
> > > f(x) = a * (1-exp(-(x-c)/b)) * exp(-x/d)
> > >
> > > Here the first exponent member is a saturation curve. This part describes the passing through of the two Be windows (chamber + before detector) and through the dead layer of Ge crystal. One needs a minimum energy to enter to the detecting Ge crystal = C parameter. b parameter = characteristic absorbtion E of these nondetecting layers.
> > > The second exponent is an exponential decrease of the detector efficiency. Photons with higher energy are less detectable by the germaniums. The d parameter is the characteristic E for hard Xray and gamma (>40keV) detectability.
> > >
> > > https://www.amptek.com/internal-products/si-pin-vs-cdte-comparison
> > >
> > > //Jan's comment: the tail of this function should more or less follow a linear trend a bit above than 40 keV.
> > >
> > >
> > > In the attachment there is an example fit for 90 degree with combined 1. and 2. (before and after beamtime) calibration datasets.
> > > I made the fit with gnuplot:
> > >
> > > degrees of freedom (FIT_NDF) : 8
> > > rms of residuals (FIT_STDFIT) = sqrt(WSSR/ndf) : 0.419915
> > > variance of residuals (reduced chisquare) = WSSR/ndf : 0.176329
> > > p-value of the Chisq distribution (FIT_P) : 0.994094
> > >
> > > Final set of parameters Asymptotic Standard Error
> > > ======================= ==========================
> > > a = 0.00308376 +/- 0.0005144 (16.68%)
> > > c = 15.6259 +/- 2.035 (13.03%)
> > > b = 9.36888 +/- 3.16 (33.73%)
> > > d = 177.141 +/- 84.95 (47.95%)
> > >
> > > Laszlo's out.
Attachment 1: 90degree_efficiency_combined.png
90degree_efficiency_combined.png
Attachment 2: 90degree_efficiency_combined.ps
90degree_efficiency_combined.ps
  282   Tue May 19 16:48:15 2020 LaszloGeneralE127 beamtime overview 
Here is a representation how was the time management during E127. The time, what we could spend with measuring the 118Te(pg), was ~20% comparing to the given 6days.
Attachment 1: E127_beamtime_overview.png
E127_beamtime_overview.png
Attachment 2: E127_beamtime_overview.pdf
E127_beamtime_overview.pdf
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