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Feedback Processes Modulating the Sensitivity of Atlantic Thermohaline Circulation to Freshwater Forcing Timescales

  • Hyo-Jeong Kim (Department of Atmospheric Sciences/Irreversible Climate Change Research Center) ;
  • Soon-Il An (Department of Atmospheric Sciences/Irreversible Climate Change Research Center) ;
  • Soong-Ki Kim (Department of Atmospheric Sciences/Irreversible Climate Change Research Center) ;
  • Jae-Heung Park (Division of Environmental Science and Engineering, Pohang University of Science and Technology)
  • Received : 2020.11.23
  • Accepted : 2021.03.18
  • Published : 20210000

Abstract

Paleoproxy records indicate that abrupt changes in thermohaline circulation (THC) were induced by rapid meltwater discharge from retreating ice sheets. Such abrupt changes in the THC have been understood as a hysteresis behavior of a nonlinear system. Previous studies, however, primarily focused on a near-static hysteresis under fixed or slowly varying freshwater forcing (FWF), reflecting the equilibrated response of the THC. This study aims to improve the current understanding of transient THC responses under rapidly varying forcing and their dependency on forcing time scales. The results simulated by an Earth system model suggest that the bifurcation is delayed as the forcing time scale is shorter, causing the Atlantic meridional overturning circulation collapse and recovery to occur at higher and lower FWF values, respectively. The delayed shutdown/recovery occurs because bifurcation is determined not by the FWF value at the time but by the total amount of freshwater remaining over the THC convection region. The remaining freshwater amount is primarily determined by the forcing accumulation (i.e., time-integrated FWF), which is modulated by the freshwater/salt advection by ocean circulations and freshwater flux by the atmospheric hydrological cycle. In general, the latter is overwhelmed by the former. When the forced freshwater amount is the same, the modulation effect is stronger under slowly varying forcing because more time is provided for the feedback processes.

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Acknowledgement

This research was supported by the Basic Science Research Program through the National Research Foundation of Korea (NRF-2017K1A3A7A03087790, NRF-2018R1A5A1024958). Author H.-J. Kim is grateful for financial support from the Hyundai Motor Chung Mong Koo Foundation. The authors also thank the editor and anonymous reviewers for providing insightful suggestions.