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Iron Speciation in Respirable Particulate Matter and Implications for Human Health

Peggy A. O’Day, Ajith Pattammattel, Paul Aronstein, Valerie J. Leppert, Henry Jay Forman

2022Environmental Science & Technology50 citationsDOIOpen Access PDF

Abstract

was present in spatially and temporally variable mixtures, mostly as Fe(III) oxides and phyllosilicates, but with significant fractions of metallic iron (Fe(0)), Fe(II,III) oxide, and Fe(III) bonded to organic carbon. Fe(0) was present as aggregated, nm-sized particles that comprised up to ∼30% of the Fe spectral fraction. Mixtures reflect anthropogenic and geogenic particles subjected to environmental weathering, but reduced Fe in PM originates from anthropogenic sources, likely as abrasion products. Possible mechanistic pathways involving Fe(0) particles and mixtures of Fe(II) and Fe(III) surface species may generate hydrogen peroxide and oxygen-centered radical species (hydroxyl, hydroperoxyl, or superoxide) in Fenton-type reactions. From a health perspective, PM mixtures with reduced and oxidized Fe will have a disproportionate effect in cellular response after inhalation because of their tendency to shuttle electrons and produce oxidants and electrophiles that induce inflammation and oxidative stress.

Topics & Concepts

ParticulatesEnvironmental chemistryChemistryIron oxideOrganic chemistryAir Quality and Health ImpactsAtmospheric chemistry and aerosolsEnergy and Environment Impacts
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