Difference between revisions of "Neutron Polarimeter"
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And in the plot below I have overlay my error calculations using the formulas above: | And in the plot below I have overlay my error calculations using the formulas above: | ||
− | [[File:Tgamma | + | [[File:Tgamma error01.png | 1000 px]] |
Revision as of 06:05, 6 April 2011
Four-vector Algebra
Consider two bode reaction
:
Write down four-momentum vectors before and after reaction:
Now apply the law of conservation of four-momentum vectors:
Squaring both side of equation above and using the four-momentum invariants
we have:
Detector located at case
Detector is located at
, and the formula above is simplified:
We can easily solve the equation above with respect to incident photon energy:
For non-relativistic neutrons and the formula above is become:
Substituting the corresponding masses, we get finally:
and visa versa:
Here I derived the formula [2] just inversing the formula [1]. I can as well start from exact solution above, solve this equation with respect to neutron energy, do the non-relativistic approximation and get exactly the same formula [2]. But anyway we ended up with two useful non-relativistic formulas we can analyze now:
1) from formula [1] above we can predict the threshold of reaction in direction:
2) from formula [1] above we can predict the incident photon energy based on the detected neutron energy (neutron polarimeter).
3) from formula [2] above we can predict the detected neutron energy based on the incident photon energy.
- for the incident photons up towe can detect neutrons up to
- for the incident photons up towe can detect neutrons up to
4) we can do the error calculations.
Example of error calculation
example 1
Say, we have, 10 MeV neutron with uncertainty 1 MeV, the corresponding uncertainly for photons energy is:
example 2
In the calculations below I attempted to predict the uncertainty in photons energy based on uncertainly of neutrons time of flight.
Say, the neutron's time of flight uncertainty is:
The neutron kinetic energy as function of time of flight is:
By taking derivative of the expression above we can find the relative neutron energy error:
Also we need to know the neutron time of flight as function of the neutron energy:
Say, the detector is 1.5 m away and neutron's time of flight uncertainty is:
In the table below are presented some calculation results using the formulas above:
And in the plot below I have overlay my error calculations using the formulas above: