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At high latitudes and in mountainous areas,evaluation and validation of water and energy flux simu- lations are greatly affected by systematic precipitation errors.These errors mainly come from topographic effects and undercatch of precipitation gauges.In this study,the Land Dynamics(LaD)land surface model is used to investigate impacts of systematic precipitation bias from topography and wind-blowing on water and energy flux simulation in Northwest America.The results show that topographic and wind adjustment reduced bias of streamflow simulations when compared with observed streamflow at 14 basins.These system- atic biases resulted in a-50%-100% bias for runoff simulations,a-20%-20% bias for evapotranspiration, and a-40%-40% bias for sensible heat flux,subject to different locations and adjustments,when compared with the control run.Uncertain gauge adjustment leads to a 25% uncertainty for precipitation,a 20%-100% uncertainty for runoff simulation,a less-than-10% uncertainty for evapotranspiration,and a less-than-20% uncertainty for sensible heat flux.
At high latitudes and in mountainous areas, evaluation and validation of water and energy flux simu- lations are significantly affected by systematic precipitation errors. These errors mainly come from topographic effects and undercatch of precipitation gauges. In this study, the Land Dynamics (LaD) land surface model is used to investigate impacts of systematic precipitation bias from topography and wind-blowing on water and energy flux simulation in Northwest America. The results show that topographic and wind adjustment reduced bias of streamflow simulations when compared with observed streamflow at 14 basins. These system- atic biases resulted in a-50% -100% bias for runoff simulations, a-20% -20% bias for evapotranspiration, and a-40% -40% bias for sensible heat flux, subject to different locations and adjustments , when compared with the control run. Uncertain gauge adjustment leads to a 25% uncertainty for precipitation, a 20% -100% uncertainty for runoff simulation, a less-than-10% uncertainty for evap otranspiration, and a less-than-20% uncertainty for sensible heat flux.