Atmospheric and oceanic energy transport during North Atlantic freshening events: Influences of moisture transport and hydrologic cycle feedbacks
Baek, S. H., Lora, J. M., Skinner, C. B., Fu, M., Zhu, J.. (2025). Atmospheric and oceanic energy transport during North Atlantic freshening events: Influences of moisture transport and hydrologic cycle feedbacks. Climate Dynamics, doi:https://doi.org/10.1007/s00382-025-07761-1
| Title | Atmospheric and oceanic energy transport during North Atlantic freshening events: Influences of moisture transport and hydrologic cycle feedbacks |
|---|---|
| Genre | Article |
| Author(s) | S. H. Baek, J. M. Lora, C. B. Skinner, M. Fu, Jiang Zhu |
| Abstract | Analogs of present-day rapid ice melt can be found in episodic discharges of icebergs that occurred during glacial periods called Heinrich events. This introduces excess meltwater into the North Atlantic and weakens the Atlantic thermohaline circulation (AMOC), triggering a hydrologic cycle–AMOC collapse feedback as the atmospheric energy transport compensates for reduced northward heat transport. Here we employ a novel series of 100-year North Atlantic “hosing” simulations to investigate atmospheric and oceanic energy transport response from freshwater forcing, focusing in particular on the role of atmospheric rivers (ARs) within atmospheric energy transport. Importantly, we use an “overwriting” methodology that allow us to attribute AMOC weakening to added North Atlantic meltwater and subsequent hydrologic cycle responses, respectively. In contrast to far-reaching response of transient eddies, our results show a substantial increase in moisture convergence from ARs that is geographically constrained to the North Atlantic midlatitudes. Such AR changes nevertheless comprise an important component of net precipitation changes over the Euro-Atlantic sector, with the amount being comparable to that from transient eddies over the subpolar Atlantic. Over the course of the century-long simulations, we demonstrate that hydrologic cycle responses to North Atlantic freshening and subsequent feedbacks, including those from ARs, account for approximately half of the simulated AMOC collapse. Our work highlights the dynamics of atmospheric moisture transport response to North Atlantic freshening events and elucidates how intensifying moisture transport may accelerate AMOC collapse in the future. |
| Publication Title | Climate Dynamics |
| Publication Date | Aug 1, 2025 |
| Publisher's Version of Record | https://doi.org/10.1007/s00382-025-07761-1 |
| OpenSky Citable URL | https://n2t.net/ark:/85065/d7m049wm |
| OpenSky Listing | View on OpenSky |
| CGD Affiliations | PPC |