Soil & Water Res., 2019, 14(4):229-239 | DOI: 10.17221/142/2018-SWR

Soil water response to rainfall in a dune-interdune landscape in Horqin Sand Land, northern ChinaOriginal Paper

Xueya Zhou1,2, Dexin Guan2, Jiabing Wu2, Fenghui Yuan2, Anzhi Wang*,2, Cangjie Jin2, Yushu Zhang3
1 Key Laboratory of Geospatial Technology for the Middle and Lower Yellow River Regions, Ministry of Education, College of Environment and Planning, Henan University, Kaifeng, P.R. China
2 Key Laboratory of Forest Ecology and Management, Institute of Applied Ecology, Chinese Academy of Sciences, Shenyang, P.R. China
3 Institute of Atmospheric Environment, China Meteorological Administration, Shenyang, P.R. China

Soil water dynamic is considered an important process for water resource and plantation management in Horqin Sand Land, northern China. In this study, soil water content simulated by the SWMS-2D model was used to systematically analyse soil water dynamics and explore the relationship between soil water and rainfall among micro-landforms (i.e., top, upslope, midslope, toeslope, and bottomland) and 0-200 cm soil depths during the growing season of 2013 and 2015. The results showed that soil water dynamics in 0-20 cm depths were closely linked to rainfall patterns, whereas soil water content in 20-80 cm depths illustrated a slight decline in addition to fluctuations caused by rainfall. At the top position, the soil water content in different ranges of depths (20-40 and 80-200 cm) was near the wilting point, and hence some branches, and even entire plants exhibited diebacks. At the upslope or midslope positions, the soil water content in 20-80 or 80-200 cm depths was higher than at the top position. Soil water content was higher at the toeslope and bottomland positions than at other micro-landforms, and deep caliche layers had a positive feedback effect on shrub establishment. Soil water recharge by rainfall was closely related to rainfall intensity and micro-landforms. Only rainfalls > 20 mm significantly increased water content in > 40 cm soil depths, but deeper water recharge occurred at the toeslope position. A linear equation was fitted to the relationship between soil water and antecedent rainfall, and the slopes and R2 of the equations were different among micro-landforms and soil depths. The linear equations generally fitted well in 0-20 and 20-40 cm depths at the top, upslope, midslope, and toeslope positions (R2 value of about 0.60), with soil water in 0-20 cm depths showing greater responses to rainfall (average slope of 0.189). In 20-40 cm depths, the response was larger at the toeslope position, with a slope of 0.137. In 40-80 cm depths, a good linear fit with a slope of 0.041 was only recorded at the toeslope position. This study provides a soil water basis for ecological restoration in similar regions.

Keywords: antecedent rainfall; micro-landforms; response magnitude; soil water dynamics

Published: December 31, 2019  Show citation

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Zhou X, Guan D, Wu J, Yuan F, Wang A, Jin C, Zhang Y. Soil water response to rainfall in a dune-interdune landscape in Horqin Sand Land, northern China. Soil & Water Res. 2019;14(4):229-239. doi: 10.17221/142/2018-SWR.
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    References

    1. Allen R.G., Pereira L.S., Raes D., Smith M. (1998): Crop Evapotranspiration - Guidelines for Computing Crop Water Requirements. FAO Irrigation and Drainage Paper 56, Rome, FAO.
    2. Brocca L., Melone F., Moramarco T., Morbidelli R. (2009): Soil moisture temporal stability over experimental areas in Central Italy. Geoderma, 148: 364-374. Go to original source...
    3. Cable J.M., Huxman T.E. (2004): Precipitation pulse size effect on Sonoran Desert soil microbial crusts. Oecologia, 141: 317-324. Go to original source... Go to PubMed...
    4. Cao C.Y., Jiang S.Y., Ying Z., Zhang F.X., Han X.S. (2011): Spatial variability of soil nutrients and microbiological properties after the establishment of leguminous shrub Caragana microphylla Lam. plantation on sand dune in the Horqin Sandy Land of Northeast China. Ecological Engineering, 37: 1467-1475. Go to original source...
    5. Feddes R.A., Kowalik P., Kolinskamalinka K., Zaradny H. (1976): Simulation of field water-uptake by plants using a soil-water dependent root extraction function. Journal of Hydrology, 31: 13-26. Go to original source...
    6. Gribb M.M., Sewell G. (1998): Solution of ground water flow problems with general purpose and special purpose computer codes. Ground Water, 36: 366-372. Go to original source...
    7. He Z.B., Zhao W.Z., Liu H., Chang X.X. (2012): The response of soil moisture to rainfall event size in subalpine grassland and meadows in a semi-arid mountain range: A case study in northwestern China's Qilian Mountains. Journal of Hydrology, 420: 183-190. Go to original source...
    8. Hennessy J.T., Gibbens R.P., Tromble J.M., Cardenas M. (1983): Water properties of caliche. Journal of Range Management, 36: 723-726. Jia D.Y., Wen J., Zhang T.T., Xi J.J. (2016): Responses of soil moisture and thermal conductivity to precipitation in the mesa of the Loess Plateau. Environmental Earth Sciences, 75: 395.
    9. Jian S.Q., Zhao C.Y., Fang S.M., Yu K. (2015): Effects of different vegetation restoration on soil water storage and water balance in the Chinese Loess Plateau. Agricultural and Forest Meteorology, 206: 85-96. Go to original source...
    10. Kandelous M.M., Šimůnek J. (2010): Numerical simulations of water movement in a subsurface drip irrigation system under field and laboratory conditions using HYDRUS-2D. Agricultural Water Management, 97: 1070-1076. Go to original source...
    11. Kurc S.A., Small E.E. (2007): Soil moisture variations and ecosystem-scale fluxes of water and carbon in semiarid grassland and shrubland. Water Resources Research, 43: 1-13. Go to original source... Go to PubMed...
    12. Li X.R., Ma F.Y., Xiao H.L., Wang X.P., Kim K.C. (2004): Long-term effects of revegetation on soil water content of sand dunes in arid region of Northern China. Journal of Arid Environments, 57: 1-16. Go to original source...
    13. Li X.Y., Zhang S.Y., Peng H.Y., Hu X., Ma Y.J. (2013): Soil water and temperature dynamics in shrub-encroached grasslands and climatic implications: Results from Inner Mongolia steppe ecosystem of north China. Agricultural and Forest Meteorology, 171: 20-30. Go to original source...
    14. Liu X.P., He Y.H., Zhao X.Y., Zhang T.H., Li Y.L., Yun J.Y., Wei S.L., Yue X.F. (2016): The response of soil water and deep percolation under Caragana microphylla to rainfall in the Horqin Sand Land, northern China. Catena, 139: 82-91. Go to original source...
    15. Niu C.Y., Musa A., Zong Q., Luo Y.M., Toshio O., Sun G.F., Liu Q. (2013): Allocation patterns of above-and belowground biomass of Caragana microphylla in Horqin Sandy Land, north China. Chinese Journal of Ecology, 32: 1980-1986. (in Chinese, English abstract)
    16. Puri S., Stephen H., Ahmad S. (2011): Relating TRMM precipitation radar land surface backscatter response to soil moisture in the Southern United States. Journal of Hydrology, 402: 115-125. Go to original source...
    17. Schaap M.G., Leij F.J. (1998): Database-related accuracy and uncertainty of pedotransfer functions. Soil Science, 163: 765-779. Go to original source...
    18. Schade J.D., Hobbie S.E. (2005): Spatial and temporal variation in islands of fertility in the Sonoran Desert. Biogeochemistry, 73: 541-543. Go to original source...
    19. Schlueter S., Vogel H.J., Ippisch O., Vanderborght J. (2013): Combined impact of soil heterogeneity and vegetation type on the annual water balance at the field scale. Vadose Zone Journal, 12: 1-17. Go to original source...
    20. Schwinning S., Sala O.E. (2004): Hierarchy of responses to resource pulses in and and semi-arid ecosystems. Oecologia, 141: 211-220. Go to original source... Go to PubMed...
    21. Scott R.L., Cable W.L., Hultine K.R. (2008): The ecohydrologic significance of hydraulic redistribution in a semiarid savanna. Water Resources Research, 44: 1-12. Go to original source...
    22. Šimůnek J., Vogel T., Van Genuchten M.T. (1994): The SWMS-2D Code for Simulating Water Flow and Solute Transport in Two-dimensional Variably Saturated Media (Version 1.21), Research Report No. 132, U.S. Salinity Laboratory Agricultural Research Service, Riverside, USDA.
    23. Šimůnek J., Van Genuchten M.T., Šejna M. (2008): Development and applications of the HYDRUS and STANMOD software packages and related codes. Vadose Zone Journal, 7: 587-600. Go to original source...
    24. Svetlitchnyi A.A., Plotnitskiy S.V., Stepovaya O.Y. (2003): Spatial distribution of soil water content within catchments and its modeling on the basis of topographic data. Journal of Hydrology, 277: 50-60. Go to original source...
    25. Thomas Z., Molenat J., Caubel V., Grimaldi C., Merot P. (2008): Simulating soil-water movement under a hedgerow surrounding a bottomland reveals the importance of transpiration in water balance. Hydrological Processes, 22: 577-585. Go to original source...
    26. Tweed S., Leblanc M., Cartwright I., Favreau G., Leduc C. (2011): Arid zone groundwater recharge and salinisation processes; an example from the Lake Eyre Basin, Australia. Journal of Hydrology, 408: 257-275. Go to original source...
    27. Van Genuchten M.T. (1980): A closed-form equation for predicting the hydraulic conductivity of unsaturated soils. Soil Science Society of America Journal, 44: 892-898. Go to original source...
    28. Vogel T., Cislerova M. (1988): On the reliability of unsaturated hydraulic conductivity calculated from the moisture retention curve. Transport in Porous Media, 3: 1-15. Go to original source...
    29. Wei Y.F., Fang J., Liu S., Zhao X.Y., Li S.G. (2013): Stable isotopic observation of water use sources of Pinus sylvestris var. mongolica in Horqin Sandy Land, China. Treesstructure and Function, 27: 1249-1260. Go to original source...
    30. Wei Z.G., Wen J., Lv S.H. (2005): A primary field experiment of land-atmosphere interaction over the loess plateau and its ground surface energy in clear day. Plateau Meteorology, 24: 545-555. (in Chinese with English abstract)
    31. Wilson D.J., Western A.W., Grayson R.B. (2004): Identifying and quantifying sources of variability in temporal and spatial soil moisture observations. Water Resources Research, 40: 1-10. Go to original source...
    32. Wu W., Geller M.A., Dickinson R.E. (2002): The response of soil moisture to long-term variability of precipitation. Journal of Hydrometeorology, 3: 604-613. Go to original source...
    33. Yang J.J., He Z.B., Du J., Chen L.F., Zhu X., Lin P.F., Li J. (2017): Soil water variability as a function of precipitation, temperature, and vegetation: a case study in the semiarid mountain region of China. Environmental Earth Sciences, 76: 206. Go to original source...
    34. Yao S.X., Zhao C.C., Zhang T.H., Liu X.P. (2013): Response of the soil water content of mobile dunes to precipitation patterns in Inner Mongolia, northern China. Journal of Arid Environments, 97: 92-98. Go to original source...
    35. Zhai Q., Rahardjo H. (2015): Estimation of permeability function from the soil-water characteristic curve. Engineering Geology, 199: 148-156. Go to original source...
    36. Zhang G.L., Don J.W., Xiao X.M., Hu Z.M., Sheldon S. (2012): Effectiveness of ecological restoration projects in Horqin Sandy Land, China based on SPOT-VGT NDVI data. Ecological Engineering, 38: 20-29. Go to original source...
    37. Zhang Y.L., Feng S.Y., Wang X.F., Binley A. (2018): Simulation of soil water flow and heat transport in drip irrigated potato field with raised beds and full plastic-film mulch in a semiarid area. Agricultural Water Management, 209: 178-187. Go to original source...
    38. Zhou X.Y., Guan D.X., Wu J.B., Yang T.T., Yuan F.H., Musa A., Jin C.J., Wang A.Z., Zhang Y.S. (2017): Quantitative investigations of water balances of a dune-interdune landscape during the growing season in the Horqin sandy land, Northeastern China. Sustainability, 9: 1-13. Go to original source...
    39. Zhu Z.D., Chen G.T. (1994): Sandy Desertification in China. Beijing, Science Press.

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