2008
DOI: 10.1016/j.gca.2008.02.022
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Formation of Zn–Ca phyllomanganate nanoparticles in grass roots

Abstract: International audienceIt is now well established that a number of terrestrial and aquatic microorganisms have the capacity to oxidize and precipitate Mn as phyllomanganate. However, this biomineralization has never been shown to occur in plant tissues, nor has the structure of a natural Mn(IV) biooxide been characterized in detail. We show that the graminaceous plant Festuca rubra (red fescue) produces a Zn-rich phyllomanganate with constant Zn:Mn and Ca:Mn atomic ratios (0.46 and 0.38, respectively) when grow… Show more

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Cited by 75 publications
(70 citation statements)
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“…The two nanoparticle diameters we considered are smaller than the 3-to 6-nm coherent scattering domain in the a-b plane that has been deduced from X-ray diffraction data for biogenic and chemically-synthesized hexagonal birnessites (Villalobos et al, 2006;Grangeon et al, 2008;Lanson et al, 2008) because they represent a compromise between realistic particle size and computational cost, allowing to investigate details (Fig. 3).…”
Section: Model Structuresmentioning
confidence: 99%
“…The two nanoparticle diameters we considered are smaller than the 3-to 6-nm coherent scattering domain in the a-b plane that has been deduced from X-ray diffraction data for biogenic and chemically-synthesized hexagonal birnessites (Villalobos et al, 2006;Grangeon et al, 2008;Lanson et al, 2008) because they represent a compromise between realistic particle size and computational cost, allowing to investigate details (Fig. 3).…”
Section: Model Structuresmentioning
confidence: 99%
“…f Zn-Mn coprecipitate on plant roots (Lanson et al, 2008), based on spectra of 6KR e , chalcophanite, and Zn δ-MnO 2 d . Fig.…”
Section: Rmentioning
confidence: 99%
“…Among the trace metals of major interest, Zn appears to be influenced strongly in its biogeochemical cycling by sorption on birnessite minerals found in soils, aquifers, streams, and wetlands . Detailed molecular-scale studies of sorbed Zn 2+ species have been published for chemically-and microbially-synthesized birnessite (Manceau et al, 2002;Toner et al, 2006), natural soil and marine birnessite (Marcus et al, 2004;Manceau et al, 2007), and Zn-Mn coprecipitates on plant roots (Lanson et al, 2008). These studies reveal that Zn 2+ binds to Mn(IV) vacancy sites in hexagonal birnessite, forming triple-corner-sharing (TCS) inner-sphere surface complexes with the three surface O surrounding a vacancy.…”
Section: Introductionmentioning
confidence: 99%
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