Simultaneous dispersion–dissolution behavior of concentrated silver nanoparticle suspensions in the presence of model organic solutes
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- 作者:Mark A. Chappella ; mark.a.chappell@usace.army.mil"" rel=""nofollow ; Lesley F. Millera ; Aaron J. Georgeb ; Brad A. Pettwayb ; Cynthia L. Pricea ; Beth E. Porterb ; Anthony J. Bednara ; Jennifer M. Seitera ; Alan J. Kennedya ; Jeffery A. Steevensa
- 关键词:Nanoparticles ; Organics ; Dispersion ; Dissolution
- 刊名:Chemosphere
- 出版年:2011
- 出版时间:August 2011
- 年:2011
- 卷:84
- 期:8
- 页码:1108-1116
- 全文大小:719 K
文摘
The premise of the nanotechnology revolution is based on the increased surface reactivity of nanometer-sized particles. Thus, these newly realized applications of noble metal nanoparticles introduce new concerns about the environmental fate of these materials if released during use or product disposal. In this paper, the focus is on silver nanoparticles, a known biocidal agent. In particular, this work explores the effect of model solutes chosen for their simple chemical structure yet their ability to simulate chemical attributes common to soil humic material: a chelating molecule, EDTA; a nonionic surfactant, Brij 35; and a large polysaccharide, alginic acid. Batch systems containing concentrated (1600 mg L−1) silver nanoparticle (nAg) suspensions were equilibrated with varying additions of EDTA, Brij 35, or alginic acid to solutions containing 1 or 100 mM NaNO3 background electrolyte. In general, both EDTA and alginate were shown to exhibit poor control over nAg dispersion stability, while Brij 35 served as a good dispersant of nAg particles, showing little difference in particle size with respect to electrolyte concentration. The data also show that loading of the model organic compounds resulted in the supersaturation of dissolved Ag for most of the systems. Mechanisms by which these occurred are discussed in more detail. The evidence suggests that regardless of the effect of humics on the stability of nAg dispersions in aqueous systems, polymer loading may enhance the dissolution and release of dissolved Ag into the environment.