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Four factor formula

Formula used to calculate nuclear chain reaction growth rate

The four-factor formula, also known as Fermi's four factor formula is used in nuclear engineering to determine the multiplication of a nuclear chain reaction in an infinite medium.

Symbol	Name	Formula	Typical thermal reactor value
\eta	Reproduction factor (eta)	\eta = \frac{\nu \sigma_f^F}{\sigma_a^F} = \frac{\nu \Sigma_f^F}{\Sigma_a^F}	1.65
f	Thermal utilization factor	f = \frac{\Sigma_a^F}{\Sigma_a}	0.71
p	Resonance escape probability	p \approx \exp \left( -\frac{\sum\limits_{i=1}^{N} N_i I_{r,A,i}}{\left( \overline{\xi} \Sigma_p \right)_{mod}} \right)	0.87
\varepsilon	Fast fission factor	\varepsilon \approx 1 + \frac{1-p}{p}\frac{u_f \nu_f P_{FAF}}{f \nu_t P_{TAF} P_{TNL}}	1.02

The symbols are defined as:

\nu, \nu_f and \nu_t are the average number of neutrons produced per fission in the medium (2.43 for uranium-235).
\sigma_f^F and \sigma_a^F are the microscopic fission and absorption thermal cross sections for fuel, respectively.
\Sigma_a^F and \Sigma_a are the macroscopic absorption thermal cross sections in fuel and in total, respectively.
\Sigma_f^F is the macroscopic fission cross-section.
N_i is the number density of atoms of a specific nuclide.
I_{r,A,i} is the resonance integral for absorption of a specific nuclide.
- I_{r,A,i} = \int_{E_{th}}^{E_0} dE' \frac{\Sigma_p^{mod}}{\Sigma_t(E')} \frac{\sigma_a^i(E')}{E'}
\overline{\xi} is the average lethargy gain per scattering event.
- Lethargy is defined as decrease in neutron energy.
u_f (fast utilization) is the probability that a fast neutron is absorbed in fuel.
P_{FAF} is the probability that a fast neutron absorption in fuel causes fission.
P_{TAF} is the probability that a thermal neutron absorption in fuel causes fission.
P_{TNL} is the thermal non-leakage probability

Multiplication

The multiplication factor, k, is defined as (see Nuclear chain reaction): :k = \frac{\mbox{neutron population following nth generation}}{\mbox{neutron population during nth generation}}

If k is greater than 1, the chain reaction is supercritical, and the neutron population will grow exponentially.
If k is less than 1, the chain reaction is subcritical, and the neutron population will exponentially decay.
If , the chain reaction is critical and the neutron population will remain constant.

In an infinite medium, neutrons cannot leak out of the system and the multiplication factor becomes the infinite multiplication factor, k = k_{\infty}, which is approximated by the four-factor formula.

References

Duderstadt, James. (1976). "Nuclear Reactor Analysis". John Wiley & Sons, Inc.
Lamarsh, John R.. (2001). "Introduction to nuclear engineering". Prentice Hall.
Adams, Marvin L.. (2009). "Introduction to Nuclear Reactor Theory". Texas A&M University.

Info: Wikipedia Source

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nuclear-technology radioactivity

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