Noah-MP With the Generic Crop Growth Model Gecros in the WRF Model: Effects of Dynamic Crop Growth on Land-Atmosphere Interaction

In this paper we coupled a crop growth model to the Weather Research and Forecasting model with its land surface model Noah-MP and demonstrated the influence of the weather driven crop growth on land-atmosphere (L-A) feedback. An impact study was performed at the convection permitting scale of 3 km over Germany. While the leaf area index (LAI) in the control simulation was the same for all cropland grid cells, the inclusion of the crop growth model resulted in heterogeneous crop development with higher LAI and stronger seasonality. For the analyses of L-A coupling, a two-legged metric was applied based on soil moisture, latent heat flux and convective available potential energy. Weak atmospheric coupling is enhanced by the crop model, the terrestrial coupling determines the regions with the L-A feedback. The inclusion of the crop model turns regions with no L-A feedback on this path into regions with strong positive coupling. The number of non-atmospherically controlled days between April and August is increased by 10-15 days in more than 50% of Germany. Our work shows that this impact results in a reduction of both cold bias and warm biases and thus improves the metrics of distributed added value of the monthly mean temperatures. The study confirms that the simulation of the weather driven annual phenological development of croplands for the regional climate simulations in mid-latitudes is crucial due to the L-A feedback processes and the currently observed and expected future change in phenological phases.

Automated summary

This paper couples a crop growth model with a weather model and conducts an impact study at a small scale in Germany. The results demonstrate that weather driven crop growth significantly influences land-atmosphere feedback, improving temperature biases and enhancing distributed added value.