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If you wish to cite an abstract presented at AGU25, please cite as: Author(s) (2025), Title, Abstract (Final paper number, ex: AE14B-1234) presented at AGU25, 15-19 Dec. 

Abstract Deglaciations and glacial inceptions are the two equally important transitional periods that bridge the glacial and interglacial climate states, yet our understanding of deglaciations far exceeds that of glacial inceptions. Substantial variations in deep ocean circulation accompanied the last deglaciation, and model simulations recently suggested that a weakening of the Atlantic Meridional Overturning Circulation (AMOC) also occurred at the last glacial inception (LGI; 113-119 thousand years ago), yet evidence of such a change remains inconclusive. Here, we report three Pa/Th records from the western and central North Atlantic that display an abrupt weakening of the AMOC at the LGI. The magnitude of the reconstructed AMOC weakening approaches but never reaches the level of disruptions associated with the Heinrich ice discharge events. Our results may highlight a unique period of orbitally forced abrupt circulation changes and the importance of ocean processes in setting atmospheric CO₂changes in motion. 

The formation of North Atlantic Deep Water (NADW) is an important component of the Atlantic Meridional Overturning Circulation’s redistribution of solar heat to the northern latitudes, and is sensitive to salinity perturbations in its source locations. Fresh glacial meltwater lowers the density of seawater, potentially influencing affect the strength and position of the density-driven overturning circulation. During Heinrich Stadial 1, the Laurentide Ice Sheet retreated rapidly from its maximum southeastern extent during the Last Glacial Maximum, sending icebergs and meltwater into the western North Atlantic. The Bermuda Rise is located in the deep western subtropical North Atlantic, where Antarctic Bottom Water mixes with newly formed NADW. Sediment proxy records from the Bermuda Rise have demonstrated that the strength of the NADW varied with abrupt deglacial climate changes (e.g., McManus et al., 2004, Nature). This study seeks to explore the influence of meltwater pulses from the Laurentide and Greenland ice sheets on NADW during the last deglaciation through the lens of the transport and deposition of silt and clay by deep ocean currents. We present a detailed record of fine-grained sediment provenance across the deglaciation using K’/Ar ages from Bermuda Rise Core KNR191-CDH13 (33 41.2 N, 57 36.9 W, 4583 m). The K’/Ar ages are based on measured 40Ar* (radiogenic product of 40K) and an assumed K concentration of 2% (The 40Ar* measurements are rapid and simple, allowing the development of high resolution records. Initial results from deglacial sediments on Bermuda Rise display values within the range of K’/Ar ages documented by previous studies of iceberg deposition from the North Atlantic, from ~400 to 1,200 Ma (e.g., Jantschik and Huon,1992, Eclogae geol. Helv.; Hemming et al., 2002, Chem. Geol.). 

With the threat of rising temperatures, the Atlantic Meridional Overturning Circulation (AMOC) has been predicted to slow down or stop entirely, potentially exacerbating climate dysregulation in the Atlantic region. This project looks to the geologically recent past, to examine how much and in what way Atlantic ocean circulation has fluctuated over the last ~10,000 years. From IODP expedition 397, we processed 33 samples from site U1586, the sediment core at the greatest depth from the Iberian Margin. Stable isotope analysis of benthic foraminifera microfossils found in these sediment cores is a widely used technique for reconstructing past ocean circulation patterns; δ13C is a tracer for water masses, and δ18O is a proxy for sea temperature and land ice coverage. We searched specifically for Cibicidoides wuellerstorfi foraminifera and used mass spectrometry to find their values of δ13C and δ18O throughout the time-series. Our analyses of the stable isotopes generally indicate a warm climate and strong AMOC activity throughout the Holocene. Within the time interval 3.5-2.4 ka, stable oxygen isotope analysis shows a deep water temperature change from warmer to colder conditions. The lowest δ13C value occurs within that time interval; after δ18O values dropped at 3.5 ka, and gradually started increasing, the δ13C decreased significantly at 2.8 ka. The fact that the lowest δ13C value coincides with a 1,000 year period of deep water temperature change shown in the δ18O record suggests a link between climate change and AMOC activity in the past, and supports predictions for the impact that current climate change may have on AMOC in the future. 

Climate cycles following the mid-Pleistocene transition include the coldest and longest glaciations of the Quaternary, punctuated by repeated rapid climate oscillations and sharp transitions into exceptionally warm, atmospheric CO₂-rich interglacial intervals. Such dramatic climate shifts reflect major reorganizations of the Earth system, with complex feedbacks between North Atlantic ice sheets and ocean–atmosphere carbon cycling believed to have played a central role in the pacing and amplitude of past climate variability. Yet, the response of the deep-ocean, the Earth’s largest reservoir of exchangeable carbon, to abrupt climate change remains elusive, posing a significant challenge to our understanding of the relationship between deep-ocean circulation and past, present, and future climate changes. The recently recovered sedimentary sequence from International Ocean Discovery Program Site U1587 (37°35′N, 10°22′W, 3479n meters below sea level [mbsl]), positioned in a mixing zone of northernand southern-sourced deep waters, offers a valuable archive for reconstructing orbital- to millennial-scale variations in climate and deepocean structure. This study presents new, high-resolution (~1 kyr) benthic foraminifera δ¹⁸O and δ¹³C records from Site U1587, spanning ~ 800 - 300 ka, with a focus on intense glaciations (Marine Isotope Stage [MIS] 16, 12, 10) and subsequent deglaciations (MIS 15, 11, 9). The U1587 δ¹⁸O record was aligned to the established chronology of the nearby Site U1385 (37°34′N, 10°08′W, 2578 mbsl), providing a refined age model for Site U1587 and enabling calculation of vertical δ¹³C gradients across the water column. Site U1587 consistently recorded more negative δ¹³C than the shallower Site U1385, with an average offset of –0.455‰ overall. The vertical δ¹³C gradient between sites is most pronounced during glacial intervals, reaching –1.64‰ at ~465 ka during MIS 12, and is notably reduced during interglacials, with an average of –0.264‰ in MIS 11. These results suggest enhanced deep-ocean stratification and carbon storage during intense glaciations, while the subsequent gradient collapse during deglaciations underscores the link between abrupt changes in deep-ocean circulation and rapid climate transitions into interglacial states. 

Atlantic Meridional Overturning Circulation (AMOC) circulates heat and nutrients within the Atlantic Ocean. As it plays a vital role in regulating climate, precipitation, and productivity, it is imperative to gain a deeper understanding of this system of ocean currents. This endeavor is especially urgent, as recent studies have stressed the potential impact of freshwater inputs due to anthropogenic climate change on the strength of AMOC. In addition to the uncertainty associated with the claim of a slowdown or complete collapse of AMOC in the near future, questions about the geometry of AMOC remain unanswered. For instance, intra-basin variability in North Atlantic paleocirculation (231Pa/230Th) records was observed in Gherardi et al., 2005. However, it was unclear whether different sources of Glacial North Atlantic Intermediate Water (GNAIW) or different overturning depths caused this variability. Reconstructing deep ocean circulation in the eastern North Atlantic using an assortment of geochemical proxies can provide insight into the future state of AMOC, as well as the evolution of its geometry. Here we present records of benthic foraminiferal δ18O and δ13C, and sedimentary 231Pa/230Th (a kinematic proxy for AMOC strength) from International Ocean Discovery Program (IODP) expedition 397, Iberian Margin Paleoclimate, site 1586 (37°37.7108′N, 10°42.6987′W, 4691.4 mbsl). The optimal location and depth of this site allow for a meaningful comparison to available paleocirculation records in order to determine whether AMOC strength varies zonally or with depth. We find that the benthic δ13C, export of 231Pa, and inferred strength of AMOC generally increased from the LGM to the Holocene, with significant decreases during Heinrich events 1 and 2. Additionally, the 231Pa/230Th record at this deep site in the eastern basin was found to vary in a similar pattern as that of a western site of a comparable depth, more closely than that of a shallower, proximal site on the Iberian Margin (Gherardi et al., 2005). This indicates that depth differences are more of a determining factor than zonal differences in establishing AMOC strength, revealing that different overturning depths likely influenced the variability observed between eastern and western Atlantic paleocirculation records more than different GNAIW sources.