Abstract
Engineered nanomaterials are directly applied to the agricultural soils as a part of pesticide/fertilize formulations or sludge/manure amendments. No prior reports are available to understand the surface interactions between gold nanoparticles (nAu) and soil components, including the charcoal black carbon (biochar). Retention of citrate-capped nAu on 300–700 °C pecan shell biochars occurred rapidly and irreversibly even at neutral pH where retention was less favorable. Uniform organic (primarily citrate ligands) layer on nAu was observable by TEM, and was preserved after the retention by biochar, which resulted in the aggregation or alignment along the edges of multisheets composing biochar. Retention of nAu was (i) greater on biochars than a sandy loam soil, (ii) greater at higher ionic strength and lower pH, and (iii) pyrolysis temperature-dependent: 500 < 700 ≪ 300 °C at pH 3. Collectively, carboxyl-enriched 300 °C biochar likely formed strong hydrogen bonds with the citrate layer of nAu. The charge transfer between the conduction band of nAu and π* continuum of polyaromatic sheets is likely to dominate on 700 °C biochar. Surface area-normalized retention of nAu on biochars was several orders of magnitude higher than negatively charged hydroxyl-bearing environmental surfaces, indicating the importance of black carbon in the environmental fate of engineered nanomaterials.
Highlights
Engineered nanomaterials are increasingly becoming available as the active ingredients or additives for the direct application on agricultural soils
There is an active debate in the literature regarding how tightly citrate is bound to the nAu surface, no TEM image is available to show the citrate layer on nAu
Similar resistance of citrate towards ligand exchange is possible in the presence of environmental dissolved organic carbon (DOC)
Summary
Minori Uchimiya[1], Joseph J. Similar charge transfer between polyaromatic surfaces of biochar and nAu could occur in aqueous media, and will destabilize nAu. The objective of present study was to understand the roles of citrate capping agents on the extent and reversibility of nAu retention by soil components including biochar. Experimental conditions were systematically altered to test the additional parameters influencing the surface interactions: biochar’s PZC17, aromaticity (H:C ratio), surface morphology (by TEM), and surface area (by CO2 porosimetry), and biochar-induced changes in pH, ionic strength, and DOC composition[15] These controllable parameters will allow us to investigate the relative importance of potential mechanisms: charge neutralization, pore penetration, hydrogen bonding, and charge transfer
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