In a study conducted by Department of Energy researchers at Pacific Northwest National Laboratory, scientists investigated the North Atlantic atmospheric rivers (ARs) making landfall over western Europe in the present and future climate scenarios. A multi-model ensemble of climate simulations from the Coupled Model Intercomparison Project Phase 5 (CMIP5) captured the seasonal and spatial variations of historical landfalling AR days. They found that the large inter-model variability of AR days correlates strongly with the inter-model spread of the westerly jet position. In the future under a high greenhouse gas emissions scenario, the models project the AR frequency to increase significantly by the end of this century. The increase in moisture with warmer temperatures plays a dominant role in the future increase of AR days. However, wind changes associated with the midlatitude jet shifts result in an increase in AR days poleward and a decrease in AR days equatorward in all seasons. As the model-projected jet shifts were strongly correlated with the simulated historical jet position in North Atlantic, they also correlated changes in AR days in Western Europe with the historical jet position. Hence, the observed jet position may provide an important constraint on model projected changes in ARs making landfall in Western Europe. Compared to the present, the research shows that both total and extreme precipitation induced by ARs in the future contribute more to the seasonal mean and extreme precipitation, primarily because of the increase in AR frequency.