Coe, M.T. (2000). Modeling terrestrial hydrologic systems at the continental scale: Testing the accuracy of an atmospheric GCM. Journal of Climate 13, 686-704.

Abstract:

A global HYDrological Routing Algorithm (HYDRA) is presented which simulates seasonal river discharge and changes in surface water level on a spatial resolution of 5’ longitude ´ 5’ latitude. The model is based on previous work by Coe (1998) and incorporates major improvements from that work including: (1) the ability to simulate monthly and seasonal variations in discharge and lake and wetland level; and (2) direct representation of man-made dams and reservoirs. HYDRA requires as input daily or monthly mean averages of runoff, precipitation, and evaporation either from General Circulation Model output or observations.

As an example of the utility of HYDRA in evaluating GCM simulations, the model is forced with monthly mean estimates of runoff from the National Center for Environment Prediction (NCEP) reanalysis dataset. The simulated river discharge clearly shows that although the NCEP runoff captures the large-scale features of the observed terrestrial hydrology, there are numerous differences in detail from observations. The simulated mean annual discharge is within ± 20% at only 13 of 90 fluvial gauging stations compared. In general, the discharge is overestimated for most of the northern high-latitudes, mid-continental North America, eastern Europe, central and eastern Asia, India, and northern Africa. Only in Western Europe and Eastern North America is the discharge consistently underestimated. Although there appears to be a need for improved simulation of land surface physics in the NCEP product and parameterization of flow velocities within HYDRA, the timing of the monthly mean discharge is in fair agreement with the observations.

Including lakes within HYDRA reduces the amplitude of the seasonal cycle of discharge and the magnitude of the annual mean discharge of the St Lawrence River system, in qualitative agreement with the observations. In addition, including the wetlands of the Sudd reduces the magnitude of the simulated annual discharge of the Nile River to values in better agreement with observations.

Finally, the impact of man-made dams and their reservoirs on the magnitude of monthly mean discharge can be explicitly included within HYDRA. As an example, including dams and reservoirs on the Parana River improves the agreement of the simulated mean monthly discharge with observations by reducing the amplitude of the seasonal cycle to values in good agreement with the observations.

The results of this study show that, although improvements can be obtained through better representations of flow velocities and more accurate digital elevation models, HYDRA can be a powerful tool for diagnosing simulated terrestrial hydrology and investigations of global climate change.