Scaling of infiltration rate using the similar media theory and dimensional analysis
Yıl 2018,
Cilt: 7 Sayı: 4, 308 - 317, 01.10.2018
Henry Oppong Tuffour
Mensah Bonsu
Awudu Abubakar
Janvier Bigabwa Bashagaluke
Murphy Acheampong Opoku
Jimmy Clifford Oppong
Öz
The
infiltration rates of variable soils were scaled using factors derived from the
steady state infiltrability (Ko)
and the saturated hydraulic conductivity (Ks)
based on the similar media theory and dimensional analysis. Infiltration rates
were successfully scaled when the characteristic scaling infiltration rate
equations were formulated through combination of the similar media theory and
dimensional analysis. This study disproved the earlier notion that to
successfully scale variable infiltration measurements, both sorptivity and
steady state infiltrability were required. Thus, the study revealed that using
the saturated hydraulic conductivity as a substitute for the steady state
infiltrability could predict and scale infiltration rates more accurately. The
study further highlighted the importance of the scaling factor (α) in any
characteristic equation supposedly to have been developed from the similar
media theory. Invariably, the ability of any characteristic scaling equation
containing no scaling factor to scale variable infiltration measurements
successfully could be fortuitous and not evolved from the similar media theory.
Kaynakça
- Berndtsson, R., Larson, M., 1987. Spatial variability of infiltration in a semi-arid environment. Journal of Hydrology 90(1-2): 117 – 133.
- Bonsu, M., 1997. Scaling infiltration using parameters of Philip infiltration equation. Journal of Applied Science and Technology 2(1-2): 1 – 6.
- Bonsu, M., Lal, R., 1982. Hydrological properties of some Alfisols of Western Nigeria: A comparison of field and laboratory methods. Nigerian Journal of Soil Science 3: 101 – 119.
- Bonsu, M., Laryea, K.B., 1989. Scaling the saturated hydraulic conductivity of an alfisol. European Journal of Soil Science 40(4): 731 – 742.
- Clausnitzer, V., Hopmans, J.W., Nielsen, D.R., 1992. Simultaneous scaling of soil water retention and hydraulic conductivity curves. Water Resources Research 28(1): 19 – 31.
- Elrick, D.E., Angulo-Jaramillo, R., Fallow, D.J., Reynolds, W.D., Parkin, G.W., 2002. Infiltration under constant head and falling head conditions. In: Environmental Mechanics: Water, Mass and Energy Transfer in the Biosphere. Raats, P.A.C., Smiles, D., Warrick, A.W. (Eds.). Geophysical Monograph Series Vol 129, American Geophysical Union, USA. pp. 47 – 53.
- Jury, W.A., Russo, D., Sposito, G., 1987. The spatial variability of water and solute transport properties in unsaturated soil: II. Scaling models of water transport. Hilgardia 55(4): 33 – 57.
- Kosugi, K., Hopmans, J.W., 1998. Scaling water retention curves for soils with lognormal pore size distribution. Soil Science Society of America Journal 62(6): 1496 – 1505.
- Lark, R.M. 2006. Soil properties and Pedometrics. Land Use and Land Cover, from Encyclopedia of Life Support Systems (EOLSS), Developed under the Auspices of the UNESCO. Oxford: EOLSS Publishers. Available at [Access date : 18.01.2018]: https://www.eolss.net/Sample-Chapters/C19/E1-05-07-03.pdf
- Miller, E.E., Miller, R.D. 1956. Physical theory for capillary flow phenomena. Journal of Applied Physics 27: 324.
- Philip, J.R., 1957. The theory of infiltration. 4: Sorptivity and algebraic infiltration equations. Soil Science 84(3): 257 – 264.
- Rowland, J.R.J., 1993. Dryland Farming in Africa. The Macmillan Press Ltd. London, England. 336p.
- Sharma, M.L., Gander, G.A., Hunt, C.G., 1980. Spatial variability of infiltration in a watershed. Journal of Hydrology 45(1-2): 101 – 122.
- Sharma, M.L., Luxmoore, R.J. 1979. Soil spatial variability and its consequences on simulated water balance. Water Resource Research 15(8): 1567–2573.
- Tillotson, P.M., Nielsen, D.R.,1984. Scaling factors in soil science. Soil Science Society of America Journal 48(5): 953 – 959.
- Tuffour, H.O., 2015. Physically based modelling of water infiltration with soil particle phase. Kwame Nkrumah University of Science and Technology, Department of Crop and Soil Sciences, PhD. Thesis, Kumasi, Ghana.
- Tuffour, H.O., Abubakari, A., Bashagaluke, J.B., Djagbletey, E.D., 2016. Mapping spatial variability of soil physical properties for site-specific management. International Research Journal of Engineering and Technology 3(2): 149 – 163.
- Tuffour, H.O., Bonsu, M., 2015. Application of green and ampt equation to infiltration with soil particle phase. Interna¬tional Journal of Scientific Research in Agricultural Sciences 2(4): 76 – 88.
- Tuffour, H.O., Bonsu, M., Khalid, A.A., Adjei-Gyapong, T., 2014. Scaling approaches to evaluating spatial variability of saturated hydraulic conductivity and cumulative ınfiltration of an acrisol. International Journal of Scientific Research in Knowledge 2(5): 224 – 232.
- Tuffour, H.O., Bonsu, M., Khalid, A.A., Adjei-Gyapong, T., Atakora, W.K., 2013. Evaluation of spatial variability of soil organic carbon and pH in an uprooted oil palm field. Indian Journal of Applied Agricultural Research 1(1): 69 – 86.
- van Genuchten, M.Th., 1980. A closed-form equation for predicting the hydraulic conductivity of unsaturated soils. Soil Science Society of America Journal 44(5): 892–898.
- Vogel, T., Cislerova, M., Hopmans, J.W., 1991. Porous media with linearly variable hydraulic properties. Water Resources Research 27(10): 2735 – 2741.
- Warrick, A.W., Lomen, D.O., Yates, S.R. 1985. A generalized solution to infiltration. Soil Science Society of America Journal 49(1): 34 – 38.
- Warrick, A.W., Mullen, G.J., Nielsen, D.R. 1977. Scaling field‐measured soil hydraulic properties using a similar media concept. Water Resource Research 13(2): 355 – 362.
- Webster, R., 1985. Quantitative spatial analysis of soil in the field. In: Advances in Soil Science. Stewart, B.A. (Ed.). Springer-Verlag Inc. New York, USA. pp. 1–70.
- Wells, L.G., Ward, A.D., Moore, I..D., Philips, R.E., 1986. Comparison of four infiltration models in characterizing infiltration through surface mine profiles. Transactions of ASAE 29(3): 785 – 793.
- Wu, L., Pan, L., Mitchell, J., Sanden, B., 1999. Measuring saturated hydraulic conductivity using a generalized solution for single-ring ınfiltrometers. Soil Science Society of America Journal 63(4): 788 – 792.
- Young, E.G., Price, R.I., 1981. Scaling of infiltration behavior in dissimilar porous materials. Water Resource Research 17(4): 1065 – 1070.
- Zavattaro, L., Jarvis, N., Persson, L., 1999. Use of similar media scaling to characterize spatial dependence of near saturated hydraulic conductivity. Soil Science Society of America Journal 63(3): 486 – 492.
- Zhu. J., Mohanty, B.P., 2002. Spatial averaging of van genuchten hydraulic parameters for steady-state flow in heterogeneous soils. Vadose Zone Journal 1(2): 261 – 272.
- Zhu. J., Mohanty, B.P., 2006. Effective scaling factor for transient infiltration in heterogeneous soils. Journal of Hydrology 319(1-4): 96 – 108.
Yıl 2018,
Cilt: 7 Sayı: 4, 308 - 317, 01.10.2018
Henry Oppong Tuffour
Mensah Bonsu
Awudu Abubakar
Janvier Bigabwa Bashagaluke
Murphy Acheampong Opoku
Jimmy Clifford Oppong
Kaynakça
- Berndtsson, R., Larson, M., 1987. Spatial variability of infiltration in a semi-arid environment. Journal of Hydrology 90(1-2): 117 – 133.
- Bonsu, M., 1997. Scaling infiltration using parameters of Philip infiltration equation. Journal of Applied Science and Technology 2(1-2): 1 – 6.
- Bonsu, M., Lal, R., 1982. Hydrological properties of some Alfisols of Western Nigeria: A comparison of field and laboratory methods. Nigerian Journal of Soil Science 3: 101 – 119.
- Bonsu, M., Laryea, K.B., 1989. Scaling the saturated hydraulic conductivity of an alfisol. European Journal of Soil Science 40(4): 731 – 742.
- Clausnitzer, V., Hopmans, J.W., Nielsen, D.R., 1992. Simultaneous scaling of soil water retention and hydraulic conductivity curves. Water Resources Research 28(1): 19 – 31.
- Elrick, D.E., Angulo-Jaramillo, R., Fallow, D.J., Reynolds, W.D., Parkin, G.W., 2002. Infiltration under constant head and falling head conditions. In: Environmental Mechanics: Water, Mass and Energy Transfer in the Biosphere. Raats, P.A.C., Smiles, D., Warrick, A.W. (Eds.). Geophysical Monograph Series Vol 129, American Geophysical Union, USA. pp. 47 – 53.
- Jury, W.A., Russo, D., Sposito, G., 1987. The spatial variability of water and solute transport properties in unsaturated soil: II. Scaling models of water transport. Hilgardia 55(4): 33 – 57.
- Kosugi, K., Hopmans, J.W., 1998. Scaling water retention curves for soils with lognormal pore size distribution. Soil Science Society of America Journal 62(6): 1496 – 1505.
- Lark, R.M. 2006. Soil properties and Pedometrics. Land Use and Land Cover, from Encyclopedia of Life Support Systems (EOLSS), Developed under the Auspices of the UNESCO. Oxford: EOLSS Publishers. Available at [Access date : 18.01.2018]: https://www.eolss.net/Sample-Chapters/C19/E1-05-07-03.pdf
- Miller, E.E., Miller, R.D. 1956. Physical theory for capillary flow phenomena. Journal of Applied Physics 27: 324.
- Philip, J.R., 1957. The theory of infiltration. 4: Sorptivity and algebraic infiltration equations. Soil Science 84(3): 257 – 264.
- Rowland, J.R.J., 1993. Dryland Farming in Africa. The Macmillan Press Ltd. London, England. 336p.
- Sharma, M.L., Gander, G.A., Hunt, C.G., 1980. Spatial variability of infiltration in a watershed. Journal of Hydrology 45(1-2): 101 – 122.
- Sharma, M.L., Luxmoore, R.J. 1979. Soil spatial variability and its consequences on simulated water balance. Water Resource Research 15(8): 1567–2573.
- Tillotson, P.M., Nielsen, D.R.,1984. Scaling factors in soil science. Soil Science Society of America Journal 48(5): 953 – 959.
- Tuffour, H.O., 2015. Physically based modelling of water infiltration with soil particle phase. Kwame Nkrumah University of Science and Technology, Department of Crop and Soil Sciences, PhD. Thesis, Kumasi, Ghana.
- Tuffour, H.O., Abubakari, A., Bashagaluke, J.B., Djagbletey, E.D., 2016. Mapping spatial variability of soil physical properties for site-specific management. International Research Journal of Engineering and Technology 3(2): 149 – 163.
- Tuffour, H.O., Bonsu, M., 2015. Application of green and ampt equation to infiltration with soil particle phase. Interna¬tional Journal of Scientific Research in Agricultural Sciences 2(4): 76 – 88.
- Tuffour, H.O., Bonsu, M., Khalid, A.A., Adjei-Gyapong, T., 2014. Scaling approaches to evaluating spatial variability of saturated hydraulic conductivity and cumulative ınfiltration of an acrisol. International Journal of Scientific Research in Knowledge 2(5): 224 – 232.
- Tuffour, H.O., Bonsu, M., Khalid, A.A., Adjei-Gyapong, T., Atakora, W.K., 2013. Evaluation of spatial variability of soil organic carbon and pH in an uprooted oil palm field. Indian Journal of Applied Agricultural Research 1(1): 69 – 86.
- van Genuchten, M.Th., 1980. A closed-form equation for predicting the hydraulic conductivity of unsaturated soils. Soil Science Society of America Journal 44(5): 892–898.
- Vogel, T., Cislerova, M., Hopmans, J.W., 1991. Porous media with linearly variable hydraulic properties. Water Resources Research 27(10): 2735 – 2741.
- Warrick, A.W., Lomen, D.O., Yates, S.R. 1985. A generalized solution to infiltration. Soil Science Society of America Journal 49(1): 34 – 38.
- Warrick, A.W., Mullen, G.J., Nielsen, D.R. 1977. Scaling field‐measured soil hydraulic properties using a similar media concept. Water Resource Research 13(2): 355 – 362.
- Webster, R., 1985. Quantitative spatial analysis of soil in the field. In: Advances in Soil Science. Stewart, B.A. (Ed.). Springer-Verlag Inc. New York, USA. pp. 1–70.
- Wells, L.G., Ward, A.D., Moore, I..D., Philips, R.E., 1986. Comparison of four infiltration models in characterizing infiltration through surface mine profiles. Transactions of ASAE 29(3): 785 – 793.
- Wu, L., Pan, L., Mitchell, J., Sanden, B., 1999. Measuring saturated hydraulic conductivity using a generalized solution for single-ring ınfiltrometers. Soil Science Society of America Journal 63(4): 788 – 792.
- Young, E.G., Price, R.I., 1981. Scaling of infiltration behavior in dissimilar porous materials. Water Resource Research 17(4): 1065 – 1070.
- Zavattaro, L., Jarvis, N., Persson, L., 1999. Use of similar media scaling to characterize spatial dependence of near saturated hydraulic conductivity. Soil Science Society of America Journal 63(3): 486 – 492.
- Zhu. J., Mohanty, B.P., 2002. Spatial averaging of van genuchten hydraulic parameters for steady-state flow in heterogeneous soils. Vadose Zone Journal 1(2): 261 – 272.
- Zhu. J., Mohanty, B.P., 2006. Effective scaling factor for transient infiltration in heterogeneous soils. Journal of Hydrology 319(1-4): 96 – 108.