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1. The Impact of Winds on AMOC in a Fully‐Coupled Climate Model

   https://doi.org/10.1029/2022GL101203  

   Roach, Lettie A.; Blanchard‐Wrigglesworth, Edward; Ragen, Sarah; Cheng, Wei; Armour, Kyle C.; Bitz, Cecilia M. (December 2022, Geophysical Research Letters)
2. Estimating Transient Climate Response in a Large-Ensemble Global Climate Model Simulation

   https://doi.org/10.1029/2018GL080714  

   Adams, B. K.; Dessler, A. E. (January 2019, Geophysical Research Letters)
3. Multiple Equilibria in a Coupled Climate–Carbon Model

   https://doi.org/10.1175/JCLI-D-21-0984.1  

   Zhu, Fangze; Rose, Brian E. (January 2023, Journal of Climate)

   Abstract Multiple stable equilibria are intrinsic to many complex dynamical systems, and have been identified in a hierarchy of climate models. Motivated by the idea that the Quaternary glacial–interglacial cycles could have resulted from orbitally forced transitions between multiple stable states mediated by internal feedbacks, this study investigates the existence and mechanisms of multiple equilibria in an idealized, energy-conserving atmosphere–ocean–sea ice general circulation model with a fully coupled carbon cycle. Four stable climates are found for identical insolation and global carbon inventory: an ice-free Warm climate, two intermediate climates (Cold and Waterbelt), and a fully ice-covered Snowball climate. A fifth state, a small ice cap state between Warm and Cold, is found to be barely unstable. Using custom radiative kernels and a thorough sampling of the model’s internal variability, three equilibria are investigated through the state dependence of radiative feedback processes. For fast feedbacks, the systematic decrease in surface albedo feedback from Cold to Warm states is offset by a similar increase in longwave water vapor feedback. At longer time scales, the key role of the carbon cycle is a dramatic lengthening of the adjustment time comparable to orbital forcings near the Warm state. The dynamics of the coupled climate–carbon system are thus not well separated in time from orbital forcings, raising interesting possibilities for nonlinear triggers for large climate changes. Significance Statement How do carbon cycle and other physical processes affect the physical and mathematical properties of the climate system? We use a complex climate model coupled with a carbon cycle to simulate the climate evolution under different initial conditions. Four stable climate states are possible, from the Snowball Earth, in which ice covers the whole planet, to the Warm state, an ice-free world. The carbon cycle drives the global climate change at an extremely slower pace after sea ice retreats. Sea ice and water vapor, on the other hand, constitute the major contributing factors that accelerate faster climate change. 

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4. The Impact of Parameterized Lateral Mixing on the Antarctic Circumpolar Current in a Coupled Climate Model

   https://doi.org/10.1175/JPO-D-19-0249.1  

   Ragen, Sarah; Pradal, Marie-Aude; Gnanadesikan, Anand (April 2020, Journal of Physical Oceanography)

   This study examines the impact of changing the lateral diffusion coefficient A Redi on the transport of the Antarctic Circumpolar Current (ACC). The lateral diffusion coefficient A Redi is poorly constrained, with values ranging across an order of magnitude in climate models. The ACC is difficult to accurately simulate, and there is a large spread in eastward transport in the Southern Ocean (SO) in these models. This paper examines how much of that spread can be attributed to different eddy parameterization coefficients. A coarse-resolution, fully coupled model suite was run with A Redi = 400, 800, 1200, and 2400 m 2 s −1 . Additionally, two simulations were run with two-dimensional representations of the mixing coefficient based on satellite altimetry. Relative to the 400 m 2 s −1 case, the 2400 m 2 s −1 case exhibits 1) an 11% decrease in average wind stress from 50° to 65°S, 2) a 20% decrease in zonally averaged eastward transport in the SO, and 3) a 14% weaker transport through the Drake Passage. The decrease in transport is well explained by changes in the thermal current shear, largely due to increases in ocean density occurring on the northern side of the ACC. In intermediate waters these increases are associated with changes in the formation of intermediate waters in the North Pacific. We hypothesize that the deep increases are associated with changes in the wind stress curl allowing Antarctic Bottom Water to escape and flow northward. 

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5. A study of climate model responses of the western Pacific subtropical high to El Niño diversity

   https://doi.org/10.1007/s00382-020-05500-2  

   Chen, Mengyan; Chang, Ting-Huai; Lee, Ching-Teng; Fang, Shih-Wei; Yu, Jin-Yi (January 2021, Climate Dynamics)

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