SOIL MOISTURE DYNAMICS OF CARAGANA KORSHINSKII WOODLAND IN LOESS PLATEAU OF NORTHWEST CHINA

Root water uptake is an important process of water circle and a component of water balance in the field. It should be understood better and effectively. A quantitative method of determining root water uptake should be built for efficient water use. The aims of this paper were to develop a water uptake model for single Caragana Korshinskii individual and to validate the model with soil water content in a plantation. Tube-time domain reflectometry (TDR) was used to measure soil volumetric water content, and sap flow sensors based on stem-heat technology were used to monitor locally the sap flow rates in the stems of C. Korshinskii. Root density distribution was determined and soil hydraulic characteristics parameters were fitted from measurements. A root water uptake model was established, which includes root density distribution function, potential transpiration and soil water stress-modified factor. The measured data were compared against the outputs of transpiration rate and soil water contents from the numerical simulation of the soil water dynamics that uses Richards' equation for water flow and the established root uptake model. The results showed an excellent agreement between the measured data and the simulated outputs, which indicate that the developed root water uptake model is effective and feasible.