Abstract
Abstract. Issues related to large uncertainty and parameter equifinality have posed big challenges for hydrological modeling in cold regions where runoff generation processes are particularly complicated. Tracer-aided hydrological models that integrate the transportation and fractionation processes of water stable isotope are increasingly used to constrain parameter uncertainty and refine the parameterizations of specific hydrological processes in cold regions. However, the common unavailability of site sampling of spatially distributed precipitation isotopes hampers the practical applications of tracer-aided models in large-scale catchments. This study, taking the precipitation isotope data (isotopes-incorporated global spectral model – isoGSM) derived from the isotopic general circulation models (iGCMs) as an example, explored its utility in driving a tracer-aided hydrological model in the Yarlung Tsangpo River basin (YTR; around 2×105 km2, with a mean elevation of 4875 m) on the Tibetan Plateau (TP). The isoGSM product was firstly corrected based on the biases between gridded precipitation isotope estimates and the limited site sampling measurements. Model simulations driven by the corrected isoGSM data were then compared with those forced by spatially interpolated precipitation isotopes from site sampling measurements. Our results indicated that (1) spatial precipitation isotopes derived from the isoGSM data helped to reduce modeling uncertainty and improve parameter identifiability in a large mountainous catchment on the TP, compared to a calibration method using discharge and snow cover area fraction without any information on water isotopes; (2) model parameters estimated by the corrected isoGSM data presented higher transferability to nested subbasins and produced higher model performance in the validation period than that estimated by the interpolated precipitation isotope data from site sampling measurements; (3) model calibration forced by the corrected isoGSM data successfully rejected parameter sets that overestimated glacier melt contribution and gave more reliable contributions of runoff components, indicating the corrected isoGSM data served as a better choice to provide informative spatial precipitation isotope than the interpolated data from site sampling measurements at the macro scale. This work suggested plausible utility of combining isoGSM data with measurements, even from a sparse sampling network, in improving hydrological modeling in large high mountain basins.
Highlights
Large uncertainty and strong equifinality of parameter calibration are the widely recognized issues in hydrological modeling (Gupta et al, 2008), especially in cold regions where hydrological complexity is highly enhanced by the competition of multiple water inputs and the strong spa-Published by Copernicus Publications on behalf of the European Geosciences Union.Y
The utility of the precipitation isotope input derived from the isotopic general circulation models product, isoGSM, in forcing the distributed tracer-aided hydrological model THREW-t in a large basin of 2 × 105 km2 on the Tibetan Plateau (TP) was investigated in this study
Our main findings are as follows: 1. Spatial precipitation isotope data derived from the isotopic general circulation models helped to reduce the modeling uncertainty and improve parameter identifiability, in comparison to a calibration method using discharge and snow cover area fraction without any information on water isotopes
Summary
Large uncertainty and strong equifinality of parameter calibration are the widely recognized issues in hydrological modeling (Gupta et al, 2008), especially in cold regions where hydrological complexity is highly enhanced by the competition of multiple water inputs and the strong spa-. The difficulty of this task is mainly related to the large uncertainty in hydrological modeling and parameter calibration in the TP because of the complex hydrological processes (He et al, 2018) and the commonly inaccurate estimation of precipitation (Xu et al, 2017; He et al, 2017). To the best of our knowledge, the only one was conducted by Delavau et al (2017), who examined the performance of an iRCM product, REMOiso, on forcing a tracer-aided model in a regional catchment of around 103 km in Canada Their results indicated that hydrological simulations driven by the iRCM product reproduced the variations of isotopic signature (δ18O) of river water comparably to the simulations driven by δ18O measurements from sampling sites and improved the representations of internal hydrological processes in the model.
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