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Journal Abstract Search

167 related items for PubMed ID: 21640358

  • 21. Retention and transport of silica nanoparticles in saturated porous media: effect of concentration and particle size.
    Wang C, Bobba AD, Attinti R, Shen C, Lazouskaya V, Wang LP, Jin Y.
    Environ Sci Technol; 2012 Jul 03; 46(13):7151-8. PubMed ID: 22642719
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  • 22. Coupled effects of solution chemistry and hydrodynamics on the mobility and transport of quantum dot nanomaterials in the vadose zone.
    Uyusur B, Darnault CJ, Snee PT, Kokën E, Jacobson AR, Wells RR.
    J Contam Hydrol; 2010 Nov 25; 118(3-4):184-98. PubMed ID: 21056511
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  • 23. TiO₂ nanoparticle transport and retention through saturated limestone porous media under various ionic strength conditions.
    Esfandyari Bayat A, Junin R, Derahman MN, Samad AA.
    Chemosphere; 2015 Sep 25; 134():7-15. PubMed ID: 25889359
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  • 24. Empirical correlations to estimate agglomerate size and deposition during injection of a polyelectrolyte-modified Fe0 nanoparticle at high particle concentration in saturated sand.
    Phenrat T, Kim HJ, Fagerlund F, Illangasekare T, Lowry GV.
    J Contam Hydrol; 2010 Nov 25; 118(3-4):152-64. PubMed ID: 20926157
    [Abstract] [Full Text] [Related]

  • 25. Deposition and release kinetics of nano-TiO2 in saturated porous media: effects of solution ionic strength and surfactants.
    Godinez IG, Darnault CJ, Khodadoust AP, Bogdan D.
    Environ Pollut; 2013 Mar 25; 174():106-13. PubMed ID: 23246754
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  • 26. Influence of natural organic matter on the aggregation and deposition of titanium dioxide nanoparticles.
    Thio BJ, Zhou D, Keller AA.
    J Hazard Mater; 2011 May 15; 189(1-2):556-63. PubMed ID: 21429667
    [Abstract] [Full Text] [Related]

  • 27. Enhanced retention of bacteria by TiO2 nanoparticles in saturated porous media.
    Gentile GJ, Fidalgo de Cortalezzi MM.
    J Contam Hydrol; 2016 Aug 15; 191():66-75. PubMed ID: 27258326
    [Abstract] [Full Text] [Related]

  • 28. Continuum-based models and concepts for the transport of nanoparticles in saturated porous media: A state-of-the-science review.
    Babakhani P, Bridge J, Doong RA, Phenrat T.
    Adv Colloid Interface Sci; 2017 Aug 15; 246():75-104. PubMed ID: 28641812
    [Abstract] [Full Text] [Related]

  • 29. Cotransport of titanium dioxide and fullerene nanoparticles in saturated porous media.
    Cai L, Tong M, Ma H, Kim H.
    Environ Sci Technol; 2013 Jun 04; 47(11):5703-10. PubMed ID: 23662648
    [Abstract] [Full Text] [Related]

  • 30. Effects of filtration-induced size change on the subsequent transport and fate of graphene oxide in saturated porous media.
    Wang M, Zuo Q, Bai Y.
    Sci Total Environ; 2021 Feb 10; 755(Pt 2):142417. PubMed ID: 33049539
    [Abstract] [Full Text] [Related]

  • 31. Hysteresis of colloid retention and release in saturated porous media during transients in solution chemistry.
    Torkzaban S, Kim HN, Simunek J, Bradford SA.
    Environ Sci Technol; 2010 Mar 01; 44(5):1662-9. PubMed ID: 20136144
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  • 33. Transport of graphene oxide in saturated porous media: effect of cation composition in mixed Na-Ca electrolyte systems.
    Fan W, Jiang XH, Yang W, Geng Z, Huo MX, Liu ZM, Zhou H.
    Sci Total Environ; 2015 Apr 01; 511():509-15. PubMed ID: 25577737
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  • 36. Aggregation and dissolution of 4 nm ZnO nanoparticles in aqueous environments: influence of pH, ionic strength, size, and adsorption of humic acid.
    Bian SW, Mudunkotuwa IA, Rupasinghe T, Grassian VH.
    Langmuir; 2011 May 17; 27(10):6059-68. PubMed ID: 21500814
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