Abstract
The runoff components were identified in the headwater area of Shule River Basin, using isotopic and chemical tracing with particular focus on the temporal variations of catchment sources. A total of 95 samples, including precipitation, groundwater, and glacial meltwater, were collected and analyzed for stable water isotopes (18O and2H) and major chemical ion parameters (potassium, sodium, calcium, magnesium, sulfate, chloride, and bicarbonate). Based on the isotope and water chemistry data, we applied end member mixing analysis (EMMA) to identify and quantify the major runoff generating sources and their contributions. The contributions of groundwater, precipitation, and glacial meltwater were 66.7%, 19.9%, and 13.4%, respectively. The study indicated that groundwater dominated runoff in the headwater area of Shule River Basin. The roles of glacier meltwater should be remarkable in water resource management in this basin. The uncertainties of the EMMA method were summarized and estimated via a classical Gaussian error propagation technique. Analyses suggested that the uncertainty in the measurement method was less important than that in the temporal and spatial variations of tracer concentrations. The uncertainty was sensitive when the difference between mixing components was small. Therefore, the variation of tracers and the difference of mixing components should be considered when hydrograph separation was applied in the basin.
Highlights
The quantification of catchment response to rainfall or snowmelt events in terms of water fluxes and chemical composition is an important issue in catchment hydrology
The hydrograph separation technique using natural tracers, in which different runoff components are quantified according to their chemical signature, is a widely used method for investigating runoff generation processes at Advances in Meteorology the catchment scale [7]
The isotopic and chemical values originate from measurement methods, field data, or the expert knowledge of the investigators. This is reasonable even if the implications of the effects are the same, since all of them cause an uncertain estimation of the end member concentrations and of the contribution of different runoff components
Summary
The quantification of catchment response to rainfall or snowmelt events in terms of water fluxes and chemical composition is an important issue in catchment hydrology. Runoff generation depends on the initial state of the various hydrological reservoirs and on the characteristics of the hydrological input (precipitation or snowmelt). Due to these factors, it is difficult to identify the dominant runoff generation processes [3]. Isotope techniques can be and successfully used to study the origin and dynamics of surface water and groundwater, evaporation of water bodies, and mixing processes between various water sources [11,12,13] To obtain both temporal and spatial origins, some investigations using stable isotopes associated with chemical tracers have been undertaken in several different basins [14, 15]. In the arid and semiarid areas, a combination of hydrologic and environmental isotope methods (18O, D) has been proved to be a valuable tool for studying processes within the water cycle and in isotope hydrology [19,20,21]
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
