%0 Journal Article %1 liu2024windsteered %A Liu, Zhengyu %A Gu, Sifan %A Zou, Sijia %A Zhang, Shaoqing %A Yu, Yangyang %A He, Chengfei %D 2024 %J Nature Geoscience %K moc-obs %R 10.1038/s41561-024-01407-3 %T Wind-steered Eastern Pathway of the Atlantic Meridional Overturning Circulation %U https://doi.org/10.1038/s41561-024-01407-3 %X The spreading pathway of the North Atlantic Deep Water, which is the lower limb of the Atlantic Meridional Overturning Circulation (AMOC), determines how climate change signals are transported throughout the global ocean. The North Atlantic Deep Water is suggested to be transported from the subpolar Atlantic to the subtropics in the western basin by the Deep Western Boundary Current and the eddy-driven interior pathway west of the Mid-Atlantic Ridge. However, much less attention has been paid to AMOC cross-gyre transport in the eastern basin. Here, combining hydrographic observations and reanalysis, we identify a robust mid-depth Eastern Pathway located east of the Mid-Atlantic Ridge, which is further corroborated by model simulations with various resolutions, including eddy-resolving simulations. The Eastern Pathway accounts for half of the North Atlantic Deep Water transport across the intergyre boundary. Sensitivity experiments suggest that the mid-depth Eastern Pathway is formed by basin-scale ocean circulation dynamics due to wind steering on the intergyre communicating window instead of bottom topography. Our results provide a model for the AMOC pathway and call for further investigations on the climate response and variabilities associated with different AMOC pathways.

@article{liu2024windsteered, abstract = {The spreading pathway of the North Atlantic Deep Water, which is the lower limb of the Atlantic Meridional Overturning Circulation (AMOC), determines how climate change signals are transported throughout the global ocean. The North Atlantic Deep Water is suggested to be transported from the subpolar Atlantic to the subtropics in the western basin by the Deep Western Boundary Current and the eddy-driven interior pathway west of the Mid-Atlantic Ridge. However, much less attention has been paid to AMOC cross-gyre transport in the eastern basin. Here, combining hydrographic observations and reanalysis, we identify a robust mid-depth Eastern Pathway located east of the Mid-Atlantic Ridge, which is further corroborated by model simulations with various resolutions, including eddy-resolving simulations. The Eastern Pathway accounts for half of the North Atlantic Deep Water transport across the intergyre boundary. Sensitivity experiments suggest that the mid-depth Eastern Pathway is formed by basin-scale ocean circulation dynamics due to wind steering on the intergyre communicating window instead of bottom topography. Our results provide a model for the AMOC pathway and call for further investigations on the climate response and variabilities associated with different AMOC pathways.}, added-at = {2024-03-13T15:32:12.000+0100}, author = {Liu, Zhengyu and Gu, Sifan and Zou, Sijia and Zhang, Shaoqing and Yu, Yangyang and He, Chengfei}, biburl = {https://www.bibsonomy.org/bibtex/21d997e4342f1579fec3a955295bf8030/laura.jackson}, day = 11, description = {Wind-steered Eastern Pathway of the Atlantic Meridional Overturning Circulation | Nature Geoscience}, doi = {10.1038/s41561-024-01407-3}, interhash = {3c07a4e8e8f7ceaa1b6ab7d390ec9a21}, intrahash = {1d997e4342f1579fec3a955295bf8030}, issn = {1752-0908}, journal = {Nature Geoscience}, keywords = {moc-obs}, month = mar, timestamp = {2024-03-13T15:32:12.000+0100}, title = {Wind-steered Eastern Pathway of the Atlantic Meridional Overturning Circulation}, url = {https://doi.org/10.1038/s41561-024-01407-3}, year = 2024 }