.ThermoSysPro.NuclearCore.Xenon

xenon as fission product

Information

# Xenon Evolution 

The Xenon evolution follows the following Bateman equations:

$$ \frac{dI^{135}}{dt} = FissionRate * \gamma_I - I^{135}  \lambda_I $$

$$ \frac{dXe^{135}}{dt} = FissionRate * \gamma_{Xe} + I^{135}  \lambda_I - Xe^{135}  \lambda_{Xe} - \Phi_{Th} Xe^{135} \sigma_{Xe} $$

where \\(\gamma\\) is the fission yield, \\(\lambda\\) the decay constant, \\(\Phi_{Th}\\) the thermal neutron flux 
and \\(\sigma_{Xe}\\) the microscopic absorption cross section of the Xenon.

The *FissionRate* is computed from the thermal power:

$$  Power / Vfuel = FissionEnergy * FissionRate $$

and \\(\Phi_{Th}\\) from the *FissionRate*, taking into account a small amount of fast fissions:

$$ FissionRate = FastFissionFactor * \Phi_{Th} * \sigma_f * N_f $$

where *FastFissionFactor* is the ratio between the total number of fissions and the thermal ones, \\(\sigma_f\\) the microscopic fission cross-section of the fuel
and \\(N_f\\) the density of fissil atoms in the fuel.

The used microscopic cross-section values should refer to the thermal neutron flux.

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## ThermoSysPro Version 4.2  

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