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References
Aguilar JR (2013) Analysis of grain size distribution and hydraulic conductivity for a variety of sediment types with application to wadi sediments. MSc Thesis, King Abdullah University of Science and Technology, Thuwal, Jordan
Barr DW (2001) Coefficient of permeability determined by measurable parameters. Ground Water 39(3):356–361
Barth GR, Hill MC, Illangasekare TH, Rajaram H (2001) Predictive modeling of flow and transport in a two-dimensional intermediate-scale, heterogeneous porous medium. Water Resour Res 37(10):2503–2512
Bear J (1972) Dynamics of fluid in porous media. Elsevier, New York
Bear J, Cheng A (2010) Modeling groundwater flow and contaminant transport. Springer, New York
Critchley K, Rudolph DL, Devlin JF, Schillig PC (2014) Stimulating in situ denitrification in an aerobic, highly permeable municipal drinking water aquifer. J Contam Hydrol 171:66–80
Devlin JF (2015) HydrogeoSieveXL: an Excel-based tool to estimate hydraulic conductivity from grain size analysis. Hydrogeol J 23:837–844
Devlin JF (2016) J.F. Devlin homepage: Professor, Department of Geology, University of Kansas. http://www.people.ku.edu/~jfdevlin/Software.html . Accessed November 2016
Dullien FA (1991) Fluid transport and pore structure. Academic, San Diego
Irani R, Callis C (1963) Particle size: measurement interpretation and application. Wiley, New York
Ishaku JM, Gadzama EW, Kaigama U (2011) Evaluation of empirical formulae for the determination of hydraulic conductivity based on grain-size analysis. J Geol Min Res 3(4):105–113
Mackay DM, Freyberg DL, Roberts PV (1986) A natural gradient experiment on solute transport in a sand aquifer: 1. approach and overview of plume movement. Water Resour Res 22(13):2017–2029
Odong J (2013) Evaluation of empirical formulae for determination of hydraulic conductivity based on grain-size analysis. Int J Agric Environ 1:1–8
Onur EM (2014) Predicting the permeability of sandy soils from grain size distributions. MSc Thesis, Kent State University, Kent, OH, USA
Rosas J, Lopez O, Missimer TM, Coulibaly KM, Dehwah AHA, Sesler K, Lujan LR, Mantilla D (2014) Determination of hydraulic conductivity from grain-size distribution for different depositional environments. Groundwater 52(3):399–413
Schillig, PC (2012) Hydrogeologic controls on bioactive zone development in biostimulated aquifers. PhD Thesis, University of Kansas, Lawrrence, KS, USA
KU ScholarWorks (2016) HydrogeoSieveXL: an Excel-based tool to estimate hydraulic conductivity from grain-size analysis. http://hdl.handle.net/1808/21763. Accessed November 2016
Thomson N, Sra K, Xu X (2007) Improved understanding of in situ chemical oxidation soil reactivity. Strategic Environmental Research and Development Program (SERDP), SERDP Project ER-1289, May, SERDP, Alexandria, VA
Todd DK (1959) Ground water hydrology. Wiley, New York
Urumović K, Urumović K Sr (2016) The referential grain size and effective porosity in the Kozeny–Carman model. Hydrol Earth Syst Sci 20:1669–1680
Vukovic M, Soro A (1992) Determination of hydraulic conductivity of porous media from grain-size composition. Water Resources Publications, Littleton, CO
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An erratum to this article is available at http://dx.doi.org/10.1007/s10040-016-1529-1.
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Devlin, J.F. Reply to Comment on “HydrogeoSieveXL: an Excel-based tool to estimate hydraulic conductivity from grain-size analysis”: technical note published in Hydrogeology Journal (2015) 23: 837–844, by J. F. Devlin. Hydrogeol J 25, 593–596 (2017). https://doi.org/10.1007/s10040-016-1510-z
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DOI: https://doi.org/10.1007/s10040-016-1510-z