Speciation controls the kinetics of iron hydroxide precipitation and transformation

TL;DR

This study develops a predictive model for iron hydroxide mineral formation, revealing how speciation influences the kinetics of ferrihydrite precipitation and transformation to goethite in aqueous systems.

Contribution

It introduces a comprehensive partial equilibrium model that accurately predicts iron mineral transformation kinetics based on mechanistic steps and speciation effects.

Findings

Goethite forms from solution and is limited by ferrihydrite dissolution.

Precipitation kinetics depend on Fe(III) hydrolysis environment.

Model applies across various pH conditions.

Abstract

The formation of energetically favourable and metastable mineral phases within the Fe-H2O system controls the long-term mobility of iron complexes as well as other aqueous phase constituents in natural aquifers, soils and other environmentally and industrially relevant systems. The fundamental mechanism controlling the formation of these solid phases has remained enigmatic. Here, we develop a general state-of-the-art partial equilibrium model and succeed in predicting the rate of amorphous 2-line ferrihydrite precipitation, dissolution and overall transformation to crystalline goethite at alkaline pH. All mechanistic steps constituting the transformation mechanism accurately predict the experimentally measured solid and aqueous phase composition over time, involving only a single kinetic rate constant each. It is found that the precipitation of goethite (i) occurs from solution and (ii) is limited by the comparatively slow dissolution of the first forming amorphous phase 2-line ferrihydrite. A generalised transformation mechanism applicable to near-neutral and mildly acidic pH further illustrates that differences in the kinetics of Fe(III) precipitation are controlled by the coordination environment of the predominant Fe(III) hydrolysis product. Findings provide a framework for the modelling of other iron(bearing) phases across a broad range of aqueous phase compositions.