Nanoscale observations of Fe(ii)-induced ferrihydrite transformation

Because of its sorption properties, transformation of the nanomineral ferrihydrite (Fh) into more stable lepidocrocite (Lp) or goethite (Gt) has important impacts on the fate of metals, nutrients, and contaminants in soils/sediments. Although it is well known that the transformation rate is greatly accelerated under suboxic conditions by aqueous Fe(ii), the enabling mass transfer process remains an ongoing debate among various mechanisms including dissolution/reprecipitation, solid-state recrystallization, and particle-mediated growth. Here, using electron microscopy, we examine the mineralogical evolution of 2-line Fh to Lp/Gt catalyzed by Fe(ii) under strict anoxic conditions, including evaluation of Cl-SO4-HCO3 anion effects. Emergence of Lp/Gt crystallites at the nanoscale was observed at similar to 20 min of reaction, earlier than previously reported. Lp is the first phase to nucleate in Cl-rich solutions without HCO3-; whereas Lp and Gt concomitantly nucleate in SO42--rich solutions, and also when co-solute HCO3- is added. Lp crystallites nucleate as quasi-2D nanosheets one-unit-cell thick that contour the Fh surface; in contrast, rod-shaped (in Cl/SO4) or acicular needle-shaped (in HCO3) Gt crystals nucleate and grow radially outward from the Fh aggregates. Stages of transformation monitored by in situ mu-XRD coupled with aqueous Fe(ii) uptake/release measurements are correlated with a short initial sorption stage followed by the onset of Lp/Gt growth that then progresses to Lp loss in favor of Gt. Microscopy data overwhelmingly support dissolution/reprecipitation as the underlying mechanism, including direct evidence for classical ion-by-ion Lp/Gt growth and Lp dissolution. The collective findings imply that the iron mass transfer through solution to distal Lp/Gt growth fronts is a critical enabling process facilitating rapid transformation.