Difference between revisions of "Counts Rate (44 MeV LINAC)"
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<math> 53.8\ \frac{neutrons}{sec} \times \frac{1\ sec}{300\ pulses} = 0.18\ \frac{neutrons}{pulse} </math> <br><br> | <math> 53.8\ \frac{neutrons}{sec} \times \frac{1\ sec}{300\ pulses} = 0.18\ \frac{neutrons}{pulse} </math> <br><br> | ||
− | :'''53.8 neutrons/sec (1/2 mil of Ti and without detector efficiency) <= this experiment is do able''' | + | :'''53.8 neutrons/sec (1/2 mil of Ti and without detector efficiency) <= this experiment is do able''' |
− | :'''0.18 neutrons/pulse (1/2 mil of Ti and without detector efficiency) <= good for stopping pulse''' | + | :'''0.18 neutrons/pulse (1/2 mil of Ti and without detector efficiency) <= good for stopping pulse''' |
=Counts Rate for U238 (1/2 mil of Al converter)= | =Counts Rate for U238 (1/2 mil of Al converter)= |
Revision as of 06:09, 1 March 2011
LINAC parameters used in calculations
1) pulse width 50 ps
2) pulse current 50 A
3) repetition rate 300 Hz
4) energy 44 MeV
Counts Rate for U238 (1/2 mil of Ti radiadot)
Number of electrons/sec on radiator
Number of photons/sec on target
bremsstrahlung
in (10,20) MeV region we have about
0.1 photons/electrons/MeV/r.l
radiation length
r.l.(Ti) = 3.59 cm
radiator thickness = 12.5
steps together...
Alex factor (GEANT4 calculation)
Collimation factor is
6.85 % of total # of photons
then, incident flux on target is
Number of neutrons/sec
photonuclear cross section for reaction
J. T. Caldwell et all., Phys. Rev. C21, 1215 (1980):
in (10,20) MeV region the average cross section, say, is:
130 mb
target thickness,
Let's target thickness = 1 mm:
neutrons per fission
2.4 neutrons/fission
steps together...yeild
Worst Case Isotropic Neutrons
checking detector distance
we want:
the time of flight of neutron >> the pulse width
take the worst case 10 MeV neutron:
take the neutron detector 1 meter away:
23 ns >> 50 ps <= time resolution is good
geometrical factor
taking real detector 3" x 2" => S is about 40 cm^2
1 meter away
fractional solid angle =
<= geometrical acceptance
Yield
the yield per second:
the yield per pulse:
- 53.8 neutrons/sec (1/2 mil of Ti and without detector efficiency) <= this experiment is do able
- 0.18 neutrons/pulse (1/2 mil of Ti and without detector efficiency) <= good for stopping pulse
Counts Rate for U238 (1/2 mil of Al converter)
radiation length
r.l.(Al) = 8.89 cm
radiator thickness = 12.5
Calibration factor
The only difference from calculations above is:
1) radiation length:
1.41 (1/2 mil Al) / 3.48 (1/2 mil Ti) = 0.40
Yield
53.8 neutrons/sec * 0.40 = 21.5 neutrons/sec (1/2 mil of Al and without detector efficiency)
0.18 neutrons/pulse * 0.40 = 0.07 neutrons/pulse (1/2 mil of Al and without detector efficiency)
Counts Rate for Deuteron (12.5 µm Ti converter)
photonuclear cross section for reaction
A. De Graeva et all., Phys. Rev. C45, 860 (1992):
in (10,20) MeV region the average cross section, say, is:
1000 μb
target thickness,
take
, liquid (20°C):
Let's target thickness = 10 cm:
angular distribution of neutron
P. Rossi et all., Phys. Rev. C40, 2412 (1989):
relativistic kinematics
An Introduction to Nuclear and Subnuclear Physics. Emilio Segre (1964)
where
asterisks are quantities referred to CM
barred quantities refer to the velocity of the CM
calculations
20 MeV | ||||||
40 MeV |
geometrical factor
taking average for 20 and 40 MeV photons
geometrical acceptance =
Calibration factor
The only differences from calculations above are:
1) cross section correction:
1000 μb (D) / 130 mb (238U) = 1/130
2) target thickness correction:
3) neutrons per reaction correction:
1 neutron (D) / 2.4 neutrons(238U) = 1/2.4
4) geometrical factor correction:
total calibration factor is:
Yield
saying all other factors is the same =>
the yield per second :
the yield per pulse:
Summary
converter | target | neutrons/sec | neutrons/pulse |
1/2 mil Ti | 53.8 | 0.18 | |
1/2 mil Al | 21.5 | 0.07 | |
1/2 mil Ti | 25.2 | 0.08 | |
1/2 mil Al | 10.1 | 0.03 |