Difference between revisions of "Runs 4111(D2O)/4112(H2O)"
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Where uncertainty in the neutron flight pass due to the finite width of the detector (14.8 cm) <math>U(l_n) = 14.8cm/2 \cdot cos(\theta)</math> and uncertainty in zero time definition in neutron TOF spectrum <math>U(t_n)=10 ns</math> | Where uncertainty in the neutron flight pass due to the finite width of the detector (14.8 cm) <math>U(l_n) = 14.8cm/2 \cdot cos(\theta)</math> and uncertainty in zero time definition in neutron TOF spectrum <math>U(t_n)=10 ns</math> | ||
− | The neutron flight path length was calculated using the following expression: <math>l_n = \sqrt{l_c^2 + (X_c-X_i)^2}</math>, where <math>X_c=75/2=37.5cm</math> | + | The neutron flight path length was calculated using the following expression: <math>l_n = \sqrt{l_c^2 + (X_c-X_i)^2}</math>, where <math>X_c=75/2=37.5cm</math> is the coordinate of the middle of the neutron detector active area and <math>X_i</math> is the current x-coordinate extracted from time difference spectrum. |
Correlation between the neutron energy and neutron energy uncertainty is plotted below: | Correlation between the neutron energy and neutron energy uncertainty is plotted below: |
Revision as of 00:17, 2 October 2012
Subtraction of stops for D2O
Subtraction of the stops for each detector in the case of D2O target. The length of the active area (scintillator) of the detector is 75.3 cm.
Subtraction of stops for H2O
Subtraction of the stops for each detector in the case of H2O target:
Subtraction of D2O and H2O ToF
Normalized superimposed timing spectra from D2O(black line)/H2O(red line) targets and bin-by-bin subtraction (green line) of D2O-H2O data:
Neutron energy analysis
Neutron energy distribution data analysis for run 4111:
Errors on the neutron energy for the case of Det M:
Where uncertainty in the neutron flight pass due to the finite width of the detector (14.8 cm)
and uncertainty in zero time definition in neutron TOF spectrumThe neutron flight path length was calculated using the following expression:
, where is the coordinate of the middle of the neutron detector active area and is the current x-coordinate extracted from time difference spectrum.Correlation between the neutron energy and neutron energy uncertainty is plotted below:
The above plot may look better if you plot-vs- ( ) As the energy increased the uncertainty increases to the point the the error bar is as big as the magnitude of the energy.
Simulation of n-flight path. DetM.
Simulation of the flight path length uncertainty
for Det M(1,2) placed right below the target:Cylindrical target with dimensions of real target was used. It was filled with liquid D2. 1 MeV neutrons were generated inside the target uniformly and isotropically. The shortest distance from the target to the detector surface was 97.4 cm (corresponds to zero in the plot of the Delta_L)
The whole range fit:
Central region fit:
As can be seen we have
of ~ 3.3 cm for the whole detector (no binning).If we apply the binning (total # of events sampled
):Region 4 | Region 3 | Region 2 | Region 1 |
---|---|---|---|
x <= -18.97 cm | 0 >= x >= -18.97 cm | 0 <= x <= 18.97 cm | x >= 18.97 cm |
Experimental data Det M
The correlation of neutron energy
and its uncertainty for the case neutron ToF cut [25,65] ns:If we consider the neutron time of flight uncertainty
and then the correlation plot changes toIf we consider the neutron time of flight uncertainty
and then the correlation plot changes toIt can be concluded that the neutron energy uncertainty is really sensitive to the neutron ToF uncertainty. In our case we had a long tail in photon peak which could possibly distort the zero time definition and the precision of neutron energy calculation.
Data analysis for DetH
Simulation of n-flight path. DetH.
Simulated neutron flight pass lenrgth distribution is presented below:
The width of the distribution is about 10 cm wide.
The active area of the detector is ~ 75 cm. If we bin the detector in four, we will get for
generated events
Region 4 | Region 3 | Region 2 | Region 1 |
---|---|---|---|
x <= -18.97 cm | 0 >= x >= -18.97 cm | 0 <= x <= 18.97 cm | x >= 18.97 cm |
So it can be seen that the neutron flight path uncertainty, if taken to be the RMS in a flight path spectrum, is
.Experimental data
Data with no binning:
After binning the detector and taking for the neutron flight path uncertainty
we got:Region 4 | Region 3 | Region 2 | Region 1 |
---|---|---|---|
x <= -18.97 cm | 0 >= x >= -18.97 cm | 0 <= x <= 18.97 cm | x >= 18.97 cm |
According to my observation the uncertainty in the neutron flight path does not influence the uncertainty in neutron energy too much. Main contribution is from the zero-time definition in ToF spectrum.
Data analysis for Det_E
Simulated neutron flight path for detector F w/o binning and
events simulated:The uncertainty in neutron flight path is RMS = 2.36 cm.
Angular distribution of neutrons (experimental data):
If we apply the binning:
Region 4 | Region 3 | Region 2 | Region 1 |
---|---|---|---|
x <= -18.97 cm | 0 >= x >= -18.97 cm | 0 <= x <= 18.97 cm | x >= 18.97 cm |
Data analysis for Det_F
Simulated neutron flight path for detector F w/o binning and
events simulated:The uncertainty in neutron flight path is RMS = 2.5 cm.
If we apply the binning:
Region 4 | Region 3 | Region 2 | Region 1 |
---|---|---|---|
x <= -18.97 cm | 0 >= x >= -18.97 cm | 0 <= x <= 18.97 cm | x >= 18.97 cm |
Experimental data
Data analysis for Det_G
Simulated neutron flight path for detector F w/o binning and
events simulated:The uncertainty in neutron flight path is RMS = 3.24 cm.
If we apply the binning:
Region 4 | Region 3 | Region 2 | Region 1 |
---|---|---|---|
x <= -18.97 cm | 0 >= x >= -18.97 cm | 0 <= x <= 18.97 cm | x >= 18.97 cm |
Data analysis for Det_K
Data analysis for Det_I
Simulated neutron flight path for detector F w/o binning and
events simulated:The uncertainty in neutron flight path is RMS = 4.27 cm.
If we apply the binning:
Region 4 | Region 3 | Region 2 | Region 1 |
---|---|---|---|
x <= -18.97 cm | 0 >= x >= -18.97 cm | 0 <= x <= 18.97 cm | x >= 18.97 cm |
The uncertainty on the zero time is
. Squared value which is comparable to and the uncertainty is big while the neutron flight path uncertainty for the whole detector is ~ 3 cm and its squared value is much less than the squared value of the distance traveled by neutrons, e.g.