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Sulfidation of Nanoscale Zero-Valent Iron by Sulfide: The Dynamic Process, Mechanism, and Role of Ferrous Iron

Wenqiang Xu, Chenyun Xia, Feng He, Zhenyu Wang, Liyuan Liang

2024Environmental Science & Technology24 citationsDOI

Abstract

Sulfidation of nanoscale zerovalent iron (nZVI) can enhance particle performance. However, the underlying mechanisms of nZVI sulfidation are poorly known. We studied the effects of Fe 2+ on 24-h dynamics of nZVI sulfidation by HS – using a dosed S to Fe molar ratio of 0.2. This shows that in the absence of Fe 2+, HS – rapidly adsorbed onto nZVI particles and reacted with surface iron oxide to form mackinawite and greigite (<0.5 h). As nZVI corrosion progressed, amorphous FeS x in solution deposited on nZVI, forming S-nZVI (0.5–24 h). However, in the initial presence of Fe 2+, the rapid reaction between HS – and Fe 2+ produced amorphous FeS x, which deposited on the nZVI and corroded the surface iron oxide layer (<0.25 h). This was followed by redeposition of colloidal iron (hydr)oxide on the particle surface (0.25–8 h) and deposition of residual FeS x (8–24 h) on S-nZVI. S loading on S-nZVI was 1 order of magnitude higher when Fe 2+ was present. Surface characterization of the sulfidated particles by TEM-SAED, XPS, and XAFS verified the solution dynamics and demonstrated that S 2– and S 2 2– /S n 2– were the principal reduced S species on S-nZVI. This study provides a methodology to tune sulfur loading and S speciation on S-nZVI to suit remediation needs.

Topics & Concepts

SulfidationFerrousIron sulfideSulfideZerovalent ironNanoscopic scaleMechanism (biology)Process (computing)MackinawiteChemistryMetallurgyInorganic chemistryMaterials scienceChemical engineeringNanotechnologyPhysical chemistryEngineeringAdsorptionComputer scienceSulfurPhilosophyEpistemologyOperating systemEnvironmental remediation with nanomaterialsNanomaterials for catalytic reactionsAdvanced oxidation water treatment