Stable cluster formation in aqueous suspensions of iron oxyhydroxide nanoparticles.

Metal oxide and oxyhydroxide nanoparticles are important components of natural aqueous systems and have application in photocatalysis. Uncoated (oxyhydr)oxide nanoparticles can form charge-stabilized colloids in water, but the precise regimes of dispersion and aggregation have been determined for very few nanomaterials. We studied the colloidal behavior of approximately 6 nm nanoparticles of iron oxyhydroxide (FeOOH), a common natural nanoscale colloid, and found that these nanoparticles formed stable suspended clusters under a range of aqueous conditions. Light and X-ray scattering methods show that suspended fractal nanoclusters are formed between pH 5 and 6.6 with well-defined maximum diameters that can be varied from 25 nm to approximately 1000 nm. The nanoclusters retain a very high surface area, and persist in suspension for at least 10 weeks in solution. The process is partially reversible because optically transparent suspensions are regained when nanoparticles that aggregated and settled at pH >7 are adjusted to pH 4 without stirring. However, completely redispersed nanoparticles are not obtained even after one month. Because nanocluster formation is controlled predominantly by surface charge, we anticipate that many metal oxide and other inorganic nanoparticles will exhibit equivalent cluster-forming behavior. Our results indicate that natural nanoparticles could form stable nanoclusters in groundwater that are likely to be highly mobile, with implications for the long-range transport of surface sorbed contaminants.

[1]  M. Borkovec,et al.  Colloid-facilitated transport of strongly sorbing contaminants in natural porous media : A laboratory column study , 1996 .

[2]  Jan Groenewold,et al.  Anomalously large equilibrium clusters of colloids , 2001 .

[3]  Paul Bartlett,et al.  Dynamical arrest in attractive colloids: the effect of long-range repulsion. , 2005, Physical review letters.

[4]  L. M. McDowell-Boyer,et al.  Particle transport through porous media , 1986 .

[5]  E. A. Sudicky,et al.  Colloid‐facilitated contaminant transport in discretely fractured porous media: 1. Numerical formulation and sensitivity analysis , 1995 .

[6]  R. L. Penn,et al.  Reduction of crystalline iron(III) oxyhydroxides using hydroquinone: Influence of phase and particle size , 2005, Geochemical transactions.

[7]  J. Raper,et al.  On techniques for the measurement of the mass fractal dimension of aggregates. , 2002, Advances in colloid and interface science.

[8]  D. Jones,et al.  Processes controlling metal ion attenuation in acid mine drainage streams , 1983 .

[9]  M. O. Speidel,et al.  Metallurgy: High nickel release from 1- and 2-euro coins , 2002, Nature.

[10]  John R. Bargar,et al.  Characterization of the manganese oxide produced by Pseudomonas putida strain MnB1 , 2003 .

[11]  Chen,et al.  Structure and fractal dimension of protein-detergent complexes. , 1986, Physical review letters.

[12]  J. J. Morgan,et al.  Chemical aspects of iron oxide coagulation in water: Laboratory studies and implications for natural systems , 1990, Aquatic Sciences.

[13]  Remo Guidieri Res , 1995, RES: Anthropology and Aesthetics.

[14]  Jacob N. Israelachvili,et al.  Intermolecular and surface forces : with applications to colloidal and biological systems , 1985 .

[15]  G. G. Stokes "J." , 1890, The New Yale Book of Quotations.

[16]  Benjamin Gilbert,et al.  Molecular-Scale Processes Involving Nanoparticulate Minerals in Biogeochemical Systems , 2005 .

[17]  Menachem Elimelech,et al.  Mobile Subsurface Colloids and Their Role in Contaminant Transport , 1999 .

[18]  J. Banfield,et al.  Formation of sphalerite (ZnS) deposits in natural biofilms of sulfate-reducing bacteria. , 2000, Science.

[19]  Ponisseril Somasundaran,et al.  Particle deposition and aggregation, measurement, modeling and simulation , 1997 .

[20]  L. Koopal,et al.  Preparation and optical properties of homodisperse haematite hydrosols. , 1986 .

[21]  H. C. Hamaker The London—van der Waals attraction between spherical particles , 1937 .

[22]  P. Meakin,et al.  The structure of fractal colloidal aggregates of finite extent , 1990 .

[23]  T. Schäfer,et al.  Metal Retention and Transport on Colloidal Particles in the Environment , 2005 .

[24]  Huifang Xu,et al.  Iron oxide coatings on sand grains from the Atlantic coastal plain: High-resolution transmission electron microscopy characterization , 2001 .

[25]  T. Evans,et al.  The interfacial electrochemistry of goethite (α-FeOOH) especially the effect of CO2 contamination , 1979 .

[26]  V. V. Tkachev,et al.  Colloid Transport of Plutonium in the Far-Field of the Mayak Production Association, Russia , 2006, Science.

[27]  R. Prasher,et al.  Thermal conductivity of nanoscale colloidal solutions (nanofluids). , 2005, Physical review letters.

[28]  C. Frandsen,et al.  Spin rotation in alpha-Fe2O3 nanoparticles by interparticle interactions. , 2005, Physical review letters.

[29]  Massimo Morbidelli,et al.  A simple model for the structure of fractal aggregates. , 2003, Journal of colloid and interface science.

[30]  Jillian F. Banfield,et al.  Morphology development and crystal growth in nanocrystalline aggregates under hydrothermal conditions: insights from titania , 1999 .

[31]  M. W. Cole,et al.  van der Waals forces between nanoclusters: importance of many-body effects. , 2006, The Journal of chemical physics.

[32]  J. Banfield,et al.  Nanoparticulate Iron Oxide Minerals in Soils and Sediments: Unique Properties and Contaminant Scavenging Mechanisms , 2005 .

[33]  S. Egelhaaf,et al.  Clusters and gels in systems of sticky particles , 2004 .

[34]  M. Borkovec,et al.  Aggregation in Charge-Stabilized Colloidal Suspensions Revisited , 1998 .

[35]  Christopher B. Murray,et al.  Structural diversity in binary nanoparticle superlattices , 2006, Nature.

[36]  G. Bickert,et al.  Characterisation of short-range structure of silica aggregates—implication to sediment compaction , 2004 .

[37]  Stefano Mossa,et al.  Equilibrium cluster phases and low-density arrested disordered states: the role of short-range attraction and long-range repulsion. , 2004, Physical review letters.

[38]  Subir K. Banerjee,et al.  From Nanodots to Nanorods: Oriented aggregation and magnetic evolution of nanocrystalline goethite , 2003 .

[39]  Kyung-Sang Cho,et al.  Designing PbSe nanowires and nanorings through oriented attachment of nanoparticles. , 2005, Journal of the American Chemical Society.

[40]  Aggregation kinetics in a model colloidal suspension. , 2006, Physical review letters.

[41]  C. A. Dreiss,et al.  Small-angle neutron scattering study of concentrated colloidal dispersions: the interparticle interactions between sterically stabilized particles. , 2005, Langmuir : the ACS journal of surfaces and colloids.

[42]  P. Schurtenberger,et al.  Simultaneous light and small-angle neutron scattering on aggregating concentrated colloidal suspensions , 2022 .

[43]  J. Banfield,et al.  Aggregation-based crystal growth and microstructure development in natural iron oxyhydroxide biomineralization products. , 2000, Science.

[44]  Waite,et al.  Colloidal Fouling of Ultrafiltration Membranes: Impact of Aggregate Structure and Size. , 1999, Journal of colloid and interface science.

[45]  Frédéric Cardinaux,et al.  Equilibrium cluster formation in concentrated protein solutions and colloids , 2004, Nature.

[46]  V. Prasad,et al.  Glasslike kinetic arrest at the colloidal-gelation transition. , 2001, Physical review letters.

[47]  Durand,et al.  Static structure factor of dilute solutions of polydisperse fractal aggregates. , 1994, Physical review. B, Condensed matter.

[48]  J. Banfield,et al.  Radionuclide contamination: Nanometre-size products of uranium bioreduction , 2002, Nature.

[49]  W. Casey,et al.  The Origin of Aluminum Flocs in Polluted Streams , 2002, Science.

[50]  D. Rancourt,et al.  Nanogoethite is the dominant reactive oxyhydroxide phase in lake and marine sediments , 2003 .

[51]  P. Vilks,et al.  Field-scale colloid migration experiments in a granite fracture , 1997 .

[52]  E. Matijević,et al.  Stability and deposition phenomena of monodispersed hematite sols , 1981 .

[53]  Behrens,et al.  Absolute Aggregation Rate Constants of Hematite Particles in Aqueous Suspensions: A Comparison of Two Different Surface Morphologies. , 1997, Journal of colloid and interface science.

[54]  D. K. Smith,et al.  Migration of plutonium in ground water at the Nevada Test Site , 1999, Nature.

[55]  L. Katz,et al.  Surface Complexation Modeling: II. Strategy for Modeling Polymer and Precipitation Reactions at High Surface Coverage , 1995 .

[56]  F. Morel,et al.  Surface Complexation Modeling: Hydrous Ferric Oxide , 1990 .

[57]  E. Saiz,et al.  Colloid formation at waste plume fronts. , 2004, Environmental science & technology.

[58]  Menachem Elimelech,et al.  Particle Deposition and Aggregation: Measurement, Modelling and Simulation , 1995 .

[59]  Feng Huang,et al.  Reversible, surface-controlled structure transformation in nanoparticles induced by an aggregation state. , 2004, Physical review letters.

[60]  S. Provencher A constrained regularization method for inverting data represented by linear algebraic or integral equations , 1982 .

[61]  T. Hellweg,et al.  Influence of charge density on the swelling of colloidal poly(N-isopropylacrylamide-co-acrylic acid) microgels , 2000 .