Theoretical assessment of boron incorporation in nickel ferrite under conditions of operating nuclear pressurized water reactors (PWRs)

TL;DR

This study uses first-principles calculations combined with thermodynamic data to assess the likelihood of boron incorporation into nickel ferrite deposits in nuclear reactors, which could impact reactor safety and operation.

Contribution

It introduces a novel computational approach to evaluate boron incorporation in NiFe₂O₄ under reactor conditions, linking defect formation energies with operational parameters.

Findings

Boron can incorporate into NiFe₂O₄ as an interstitial impurity.

Boron accumulation may cause axial power shifts in reactors.

The method is applicable to other solids in aqueous equilibrium.

Abstract

A serious concern in the safety and economy of a pressurized water nuclear reactor is related to the accumulation of boron inside the metal oxide (mostly NiFe${}_{2}$O${}_{4}$ spinel) deposits on the upper regions of the fuel rods. Boron, being a potent neutron absorber, can alter the neutron flux causing anomalous shifts and fluctuations in the power output of the reactor core. This phenomenon reduces the operational flexibility of the plant and may force the down-rating of the reactor. In this work an innovative approach is used to combine first-principles calculations with thermodynamic data to evaluate the possibility of B incorporation into the crystal structure of NiFe${}_{2}$O${}_{4}$, under conditions typical to operating nuclear pressurized water nuclear reactors. Analyses of temperature and pH dependence of the defect formation energies indicate that B can accumulate in NiFe${}_{2}$O${}_{4}$ as an interstitial impurity and may therefore be a major contributor to the anomalous axial power shift observed in nuclear reactors. This computational approach is quite general and applicable to a large variety of solids in equilibrium with aqueous solutions.