[KSCI] Korea Science Citation Index Service

http://dx.doi.org/10.7745/KJSSF.2012.45.4.484

Simulation of Soil Hydrological Components in Chuncheon over 30 years Using E-DiGOR Model

Aydin, Mehmet (Department of Biological Environment, Kangwon National University)
Jung, Yeong-Sang (Department of Biological Environment, Kangwon National University)
Yang, Jae-E. (Department of Biological Environment, Kangwon National University)
Lee, Hyun-Il (Department of Biological Environment, Kangwon National University)
Kim, Kyung-Dae (Agricultural Research and Extension Service)

Publication Information

Korean Journal of Soil Science and Fertilizer / v.45, no.4, 2012 , pp. 484-491 More about this Journal

Abstract

The hydrological components of a sandy loam soil of nearly level in Chuncheon over 30 years were computed using the E-DiGOR model. Daily simulations were carried out for each year during the period of 1980 to 2009 using standard climate data. Reference evapotranspiration and potential soil evaporation based on Penman-Montheith model were higher during May to August because of the higher atmospheric evaporative demand. Actual soil evaporation was mainly found to be a function of the amount and timing of rainfall, and presumably soil wetness in addition to atmospheric demand. Drainage was affected by rainfall and increased with a higher amount of precipitation and soil water content. Excess drainage occurred throughout rainy months (from July to September), with a peak in July. Therefore, leaching may be a serious problem in the soils all through these months. The 30-year average annual reference evapotranspiration and potential soil evaporation were 951.5 mm and 714.2 mm, respectively. The actual evaporation from bare soil varied between 396.9-528.4 mm and showed comparatively lesser inter-annual variations than drainage. Annual drainage rates below 120 cm soil depth ranged from 477.8 to 1565.9 mm. The long-term mean annual drainage-loss was approximately two times higher than actual soil evaporation.

Keywords

Soil-water balance; E-DiGOR model; Reference evapotranspiration; Chuncheon;

Citations & Related Records

Times Cited By KSCI : 2 (Citation Analysis)

Reference
Cited By KSCI

1	Acs, F. 2003. A comparative analysis of transpiration and bare soil evaporation. Boundary-Layer Meteorology 109:139-162. DOI
2	Agam, N.,P.R. Berliner, A. Zangvil, and E. Ben-Dor, 2004. Soil water evaporation during the dry season in an arid zone. J. Geophys. Res.-Atm. 109, 16103. DOI
3	Allen, R.G., M. Smith, A. Perrier, and L.S. Pereira. 1994. An update for the definition of reference evapotranspiration. ICID Bulletin 43(2), pp. 92.
4	Allen, R.G., L.S. Pereira, D. Raes, and M. Smith. 1998. Crop evapotranspirtion: Guidelines for computing crop water requirements. Irrigation and Drainage paper No. 56. FAO, Rome. pp. 300.
5	Allen, R.G. 2011. Skin layer evaporation to account for small precipitation events-An enhancement to the FAO-56 evaporation model. Agric. Water Manage. 99(1):8-18. DOI
6	Aydin, M. 1998. A new model for predicting evaporation from bare field soil. Proceedings of the International Symposium and second Chinese National Conference on Rainwater Utilization, Xuzhou-Jiangsu, China:283-287.
7	Aydin, M., S.L. Yang, N. Kurt, and T. Yano. 2005. Test of a simple model for estimating evaporation from bare soils in different environments. Ecol. Model. 182:91-105. DOI
8	Aydin, M. and V. Uygur. 2006. A model for estimating soil water potential of bare fields. Proceedings of the 18th International Soil Meeting (ISM) on Soils Sustaining Life on Earth,Managing Soil and Technology, Sanliurfa, Turkey:477-480.
9	Aydin, M. 2008. A model for evaporation and drainage investigations at ground of ordinary rainfed-areas. Ecol. Model. 217(1-2): 148-156. DOI
10	Aydin, M., T. Yano, F. Evrendilek, and V. Uygur, 2008. Implications of climate change for evaporation from bare soils in a Mediterranean environment. Environ. Monit. Assess. 140:123-130. DOI
11	Aydin, M. and S. F. Kececioglu. 2010. Sensitivity analysis of evaporation module of E-DiGOR model. Turk. J. Agric. For. 34:497-507.
12	Aydin, M. and V. Polat, 2010. A computer program for E-DiGOR model. International Soil Science Congress on "Management of Natural Resources to Sustain Soil Health and Quality", 26-28 May 2010, Samsun, Turkey. Book of Proceedings (ISBN:978 -975-7636-72-4):9-16.
13	Aydin, M. 2012. Improvements in E-DiGOR model: Quantifying the water balance components of bare soils. KNU Journal of Agricultural, Life and Environmental Sciences 24(2):68-71.
14	Aydin, M., M. Vithanage, M.I.M. Mowjood, Y.-S. Jung, J.E. Yang, Y.S. Ok, S.C. Kim, and C.B. Dissanayake. 2012. Estimation of evaporation and drainage losses from two bare soils in Sri Lanka. Eurasian Journal of Soil Science 1:1-9.
15	Bittelli, M., F. Ventura, G.S. Campbell, R.L. Snyder, F. Gallegati, and P.R. Pisa. 2008. Coupling of heat, water vapor, and liquid water fluxes to compute evaporation in bare soils. J. Hydrol. 362(3-4):191-205. DOI
16	Brown, R.W. and D.M. Oosterhuis. 1992. Measuring plant and soil water potentials with thermocouple psychrometers:some concerns. Agron. J. 84:78-86. DOI
17	Jo, H-K. 2002. Impacts of urban greenspace on offsetting carbon emissions for middle Korea. J. Environ. Manage. 64:115-126. DOI
18	Burt, C.M., A.J. Mutziger, R.G. Allen, and T.A. Howell. 2005. Evaporation research: Review and interpretation. J. Irrig. Drain. E-ASCE 131(1):37-58. DOI
19	Choi, W., M. Choi, H. Oh, and J. Park. 2010. Estimation on trends of reference evapotranspiration of weather station using Reference Evapotranspiration Calculater Software. KSCE Journal of Civil Engineering 30(2B):219-231.
20	Eilers, V.H.M., R.C. Carter, and K.R. Rushton. 2007. A single layer soil water balance model for estimating deep drainage (potential recharge):an application to cropped land in semi-arid North-east Nigeria. Geoderma 140:119-131. DOI
21	Kim, S. and H-S. Kim. 2008. The integrational operation method for the modeling of pan evaporation and the alfalfa reference evapotranspiration. KSCE Journal of Civil Engineering 28(2B): 199-213. 과학기술학회마을
22	Kim, S., 2010a. Calculation of grass reference evapotranspiration (ETo) using the FAO-56 Penman-Monteith Equation. KSCE Annual Conference, p. 1569.
23	Kim, S. 2010b. The calculation of ungaged reference evapotranspiration using SVM-NNM. KSCE Annual Conference, p. 1901.
24	Konukcu, F. 2007. Modification of the penman method for computing bare soil evaporation. Hydrol. Process. 21 (26):3627-3634. DOI ScienceOn
25	Kroes, J. G., J. C. van Dam, and J. Huygan. 1999. User's guide of SWAP version 2.0. Technical document 53, DLO WSC Report 81. Wageningen: Department of Water Resources, Agricultural University.
26	Rim, C-S. 2008. Trends of annual and monthly FAO Penman-Monteith reference evapotranspiration. KSCE Journal of Civil Engineering 28 (1B):65-77. 과학기술학회마을
27	Kurt, N. 2011. Monitoring of Soil Water Budget Using E-DiGOR Model in Olive Producing Area (Ph. D. Thesis). Mustafa Kemal University, Institute of Natural and Applied Sciences, Hatay-Turkey. Code No:27.
28	Lee, K-H. and J-H. Park. 2008. Calibration of the Hargreaves Equation for the reference evapotranspiration estimation on a nation-wide scale. KSCE Journal of Civil Engineering 28(6B):675-681. 과학기술학회마을
29	Onder, D., M. Aydin, and S. Onder. 2009. Estimation of actual soil evaporation using E-DiGOR model in different parts of Turkey. Afr. J. Agric. Res. 4(5):505-510.
30	Rim, C-S. 2010. Evaluation of urban effects on trends of hydrometeorological variables. KSCE Journal of Civil Engineering 30 (1B) :71-80.
31	Ritchie, J.T. 1972. Model for predicting evaporation from a row crop with incomplete cover. Water Resour. Res. 8:1204-1213. DOI
32	Romano, E. and M. Giudici. 2009. On the use of meteorological data to assess the evaporation from a bare soil. J. Hydrol. 372 (1-4):30-40. DOI
33	Van Dam, J. C., J. Huygen, J.G. Wesseling, R.A. Feddes, P. Kabat, P.E.V. van Walsum, P. Groendijk, and C. A. van Diepen. 1997. Theory of SWAP version 2.0. Simulation of water flow, solute transport and plant growth in the Soil-Water-Atmosphere-Plant environment. Technical Document 45, DLO Winand Staring Centre, Report 71, Dept. Water Resources, Agricultural University, Wageningen. pp. 167.
34	Vanderborght, J., A. Graf, C. Steenpass, B. Scharnagl, N. Prolingheuer, M. Herbst, H.J.H. Franssen, and H. Vereecken. 2010. Withinfield variability of bare soil evaporation derived from eddy covariance Measurements. Vadose Zone Journal 9(4):943-954. DOI
35	Xu, C.-Y, L. Gong, T. Jiang, D. Chen, and V.P. Singh. 2006. Analysis of spatial distribution and temporal trend of reference evapotranspiration and pan evaporation in Changjiang (Yangtze River) catchment. J. Hydrol. 327:81-93. DOI
36	Ventura, F., R.L. Snyder, and K.M. Bali. 2006. Estimating evaporation from bare soil using soil moisture data. J. Irrig. Drain. E-ASCE. 132(2):153-158. DOI
37	Wallace, J.S., N.A. Jackson, and C.K. Ong. 1999. Modelling soil evaporation in an agroforestry system in Kenya. Agric. For. Meteorol. 94:189-202. DOI
38	Xiao, X ., R. Horton, T.J. Sauer, J.L. Heitman, and T. Ren. 2011. Cumulative soil water evaporation as a function of depth and time. Vadose Zone Journal 10(3):1016-1022. DOI