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Kinetics of Zero Valent Iron Nanoparticle Oxidation in Oxygenated Water

Lauren F. GreenleeApplied Chemicals and Materials Division and ‡Electromagnetics DivisionNational Institute of Standards and Technology 325 Broadway, Boulder, Colorado 80305, United StatesJessica D. TorreyApplied Chemicals and Materials Division and ‡Electromagnetics DivisionNational Institute of Standards and Technology 325 Broadway, Boulder, Colorado 80305, United StatesRobert L. AmaroApplied Chemicals and Materials Division and ‡Electromagnetics DivisionNational Institute of Standards and Technology 325 Broadway, Boulder, Colorado 80305, United StatesJustin M. ShawApplied Chemicals and Materials Division and ‡Electromagnetics DivisionNational Institute of Standards and Technology 325 Broadway, Boulder, Colorado 80305, United States
2012en
ABI

Abstract

Zero valent iron (ZVI) nanoparticles are versatile in their ability to remove a wide variety of water contaminants, and ZVI-based bimetallic nanoparticles show increased reactivity above that of ZVI alone. ZVI nanoparticles degrade contaminants through the reactive species (e.g., OH*, H(2(g)), H(2)O(2)) that are produced during iron oxidation. Measurement and modeling of aqueous ZVI nanoparticle oxidation kinetics are therefore necessary to optimize nanoparticle design. Stabilized ZVI and iron-nickel nanoparticles of approximately 150 nm in diameter were synthesized through solution chemistry, and nanoparticle oxidation kinetics were determined via measured mass change using a quartz crystal microbalance (QCM). Under flowing aerated water, ZVI nanoparticles had an initial exponential growth behavior indicating surface-dominated oxidation controlled by migration of species (H(2)O and O(2)) to the surface. A region of logarithmic growth followed the exponential growth which, based on the Mott-Cabrera model of thin oxide film growth, suggests a reaction dominated by movement of species (e.g., iron cations and oxygen anions) through the oxide layer. The presence of ethanol or a nickel shell on the ZVI nanoparticles delayed the onset of iron oxidation and reduced the extent of oxidation. In oxygenated water, ZVI nanoparticles oxidized primarily to the iron oxide-hydroxide lepidocrocite.

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