Reports

The Structure of Ferrihydrite, a Nanocrystalline Material

F. Marc Michel,^1,2* Lars Ehm,^1,2 Sytle M. Antao,³ Peter L. Lee,³ Peter J. Chupas,³ Gang Liu,^1,4 Daniel R. Strongin,^1,4 Martin A. A. Schoonen,^1,2 Brian L. Phillips,^1,2 John B. Parise^1,2,5

Despite the ubiquity of ferrihydrite in natural sediments and its importance as an industrial sorbent, the nanocrystallinity of this iron oxyhydroxide has hampered accurate structure determination by traditional methods that rely on long-range order. We uncovered the atomic arrangement by real-space modeling of the pair distribution function (PDF) derived from direct Fourier transformation of the total x-ray scattering. The PDF for ferrihydrite synthesized with the use of different routes is consistent with a single phase (hexagonal space group P6₃mc; a = 5.95 angstroms, c = 9.06 angstroms). In its ideal form, this structure contains 20% tetrahedrally and 80% octahedrally coordinated iron and has a basic structural motif closely related to the Baker-Figgis -Keggin cluster. Real-space fitting indicates structural relaxation with decreasing particle size and also suggests that second-order effects such as internal strain, stacking faults, and particle shape contribute to the PDFs.

¹ Center for Environmental Molecular Science (CEMS), Stony Brook University, Stony Brook, NY 11794, USA.
² Department of Geosciences, Stony Brook University, Stony Brook, NY 11794, USA.
³ Advanced Photon Source, Argonne National Laboratory, Argonne, IL 60439, USA.
⁴ Department of Chemistry, Temple University, Philadelphia, PA 19122, USA.
⁵ Department of Chemistry, Stony Brook University, Stony Brook, NY 11794, USA.

^* To whom correspondence should be addressed. E-mail: fmichel{at}ic.sunysb.edu

Read the Full Text

General model for the aqueous precipitation of rough-surface nanocrystals and application to ferrihydrite genesis.

P. Marchand and D. G. Rancourt (2009)
American Mineralogist 94, 1428-1439
 |  Abstract »  |  Full Text »  |  PDF »

Evaluation of the structural model for ferrihydrite derived from real-space modelling of high-energy X-ray diffraction data.

A. Manceau (2009)
Clay Minerals 44, 19-34
 |  Abstract »  |  Full Text »  |  PDF »

MAGNETIC ENHANCEMENT DURING THE CRYSTALLIZATION OF FERRIHYDRITE AT 25 AND 50{degrees}C.

E. Cabello, M. P. Morales, C. J. Serna, V. Barron, and J. Torrent (2009)
Clays and Clay Minerals 57, 46-53
 |  Abstract »  |  Full Text »  |  PDF »

Structure, Chemistry, and Properties of Mineral Nanoparticles.

G. A. Waychunas and H. Zhang (2008)
Elements 4, 381-387
 |  Abstract »  |  Full Text »  |  PDF »

Iron Oxides as Geochemical Nanovectors for Metal Transport in Soil-River Systems.

M. Hassellov and F. von der Kammer (2008)
Elements 4, 401-406
 |  Abstract »  |  Full Text »  |  PDF »

Constraints on structural models of ferrihydrite as a nanocrystalline material.

D.G. Rancourt and J.-F. Meunier (2008)
American Mineralogist 93, 1412-1417
 |  Abstract »  |  Full Text »  |  PDF »

Time-resolved synchrotron powder X-ray diffraction study of magnetite formation by the Fe(III)-reducing bacterium Geobacter sulfurreducens.

V. S. Coker, A. M.T. Bell, C. I. Pearce, R. A.D. Pattrick, G. van der Laan, and J. R. Lloyd (2008)
American Mineralogist 93, 540-547
 |  Abstract »  |  Full Text »  |  PDF »

Nanominerals, Mineral Nanoparticles, and Earth Systems.

M. F. Hochella Jr., S. K. Lower, P. A. Maurice, R. L. Penn, N. Sahai, D. L. Sparks, and B. S. Twining (2008)
Science 319, 1631-1635
 |  Abstract »  |  Full Text »  |  PDF »

Size-Driven Structural and Thermodynamic Complexity in Iron Oxides.

A. Navrotsky, L. Mazeina, and J. Majzlan (2008)
Science 319, 1635-1638
 |  Abstract »  |  Full Text »  |  PDF »

Adsorption studies of Mo and V onto ferrihydrite.

L. Brinza, L. G. Benning, and P. J. Statham (2008)
Mineralogical Magazine 72, 385-388
 |  Abstract »  |  Full Text »  |  PDF »

To Advertise   |   Find Products