Reflecting (on) the Nucleation Curve: Negative Surface Energy Stabilizes Nickel Ferrite Nano-Particles in Nuclear Reactor Coolant

TL;DR

This study uses thermodynamics-informed first principles calculations to reveal that negative surface energy stabilizes nickel ferrite nanoparticles in nuclear reactor coolant, suggesting new phase stability insights and implications for coolant purification.

Contribution

It introduces the reflected nucleation curve, a new fundamental relation, and predicts stable nickel ferrite clusters in PWR coolant under operational conditions.

Findings

Negative surface energy for nickel ferrite at PWR conditions

Presence of stable nickel ferrite clusters in coolant

Limitations of current coolant purification methods

Abstract

We used a thermodynamics-informed first principles scheme, to calculate the temperature-dependent surface energies of nickel oxide (NiO) and nickel ferrite (NiFe2O4), two compounds that are known to deposit on the fuel rods in nuclear pressurized water reactors (PWR). These calculations predict a negative surface free energy for nickel ferrite when formed from ions in solution under PWR conditions of temperature, pressure and species concentration. Under these conditions the thermodynamics of bulk nickel ferrite yields a positive change in free energy for formation of the solid from dissolved ions. These results and their analysis in terms of classical nucleation theory have suggested a new fundamental relation - the reflected nucleation curve - that reveals a previously unrecognized aspect of the theory of phase stability. These calculations also suggest the presence of stable octahedral nickel ferrite clusters in PWR coolant that would not be observed in the coolant outside of service conditions, and that are not removed by the combination of filtration and capture of solvated ions currently used to purify the PWR coolant.