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1. Ocean warming drives immediate mass loss from calving glaciers in the high Arctic

   https://doi.org/10.1038/s41467-024-54825-7  

   Foss, Ø.; Maton, J.; Moholdt, G.; Schmidt, L_S; Sutherland, D_A; Fer, I.; Nilsen, F.; Kohler, J.; Sundfjord, A. (December 2024, Nature Communications)

   Abstract Glaciers in the Arctic have lost considerable mass during the last two decades. About a third of the glaciers by area drains into the ocean, yet the mechanisms and drivers governing mass loss at glacier calving fronts are poorly constrained in part due to few long-term glacier-ocean observations. Here, we combine a detailed satellite-based record of calving front ablation for Austfonna, the largest ice cap on Svalbard, with in-situ ocean records from an offshore mooring and modelled freshwater runoff for the period 2018-2022. We show that submarine melting and calving occur almost exclusively in autumn for all types of outlet glaciers, even for the surging and fast-flowing glacier Storisstraumen. Ocean temperature controls the observed frontal ablation, whereas subglacial runoff of surface meltwater appears to have little direct impact on the total ablation. The seasonal warming of the offshore waters varies both in magnitude, depth and timing, suggesting a complex interplay between inflowing Atlantic-influenced water at depth and seasonally warmed surface water in the Barents Sea. The immediate response of frontal ablation to seasonal ocean warming suggests that marine-terminating glaciers in high Arctic regions exposed to Atlantification are prone to rapid changes that should be accounted for in future glacier projections. 

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2. Spatial and seasonal variability of horizontal temperature fronts in the Mozambique Channel for both epipelagic and mesopelagic realms

   https://doi.org/10.3389/fmars.2022.1045136  

   Sudre, Floriane; Dewitte, Boris; Mazoyer, Camille; Garçon, Véronique; Sudre, Joel; Penven, Pierrick; Rossi, Vincent (January 2023, Frontiers in Marine Science)

   Introduction Ocean fronts are moving ephemeral biological hotspots forming at the interface of cooler and warmer waters. In the open ocean, this is where marine organisms, ranging from plankton to mesopelagic fish up to megafauna, gather and where most fishing activities concentrate. Fronts are critical ecosystems so that understanding their spatio-temporal variability is essential not only for conservation goals but also to ensure sustainable fisheries. The Mozambique Channel (MC) is an ideal laboratory to study ocean front variability due to its energetic flow at sub-to-mesoscales, its high biodiversity and the currently debated conservation initiatives. Meanwhile, fronts detection relying solely on remotely-sensed Sea Surface Temperature (SST) cannot access aspects of the subsurface frontal activity that may be relevant for understanding ecosystem dynamics. Method In this study, we used the Belkin and O’Reilly Algorithm on remotely-sensed SST and hindcasts of a high-resolution nested ocean model to investigate the spatial and seasonal variability of temperature fronts at different depths in the MC. Results We find that the seasonally varying spatial patterns of frontal activity can be interpreted as resulting from main features of the mean circulation in the MC region. In particular, horizontally, temperature fronts are intense and frequent along continental shelves, in islands’ wakes, at the edge of eddies, and in the pathways of both North-East Madagascar Current (NEMC) and South-East Madagascar Current (SEMC). In austral summer, thermal fronts in the MC are mainly associated with the Angoche upwelling and seasonal variability of the Mozambique current. In austral winter, thermal fronts in the MC are more intense when the NEMC and the Seychelles-Chagos and South Madagascar upwelling cells intensify. Vertically, the intensity of temperature fronts peaks in the vicinity of the mean thermocline. Discussion Considering the marked seasonality of frontal activity evidenced here and the dynamical connections of the MC circulation with equatorial variability, our study calls for addressing longer timescales of variability to investigate how ocean ecosystem/front interactions will evolve with climate change. 

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3. Biomarker characterization of the North Water Polynya, Baffin Bay: implications for local sea ice and temperature proxies

   https://doi.org/10.5194/bg-20-229-2023  

   Harning, David J; Holman, Brooke; Woelders, Lineke; Jennings, Anne E; Sepúlveda, Julio (January 2023, Biogeosciences)

   Abstract. The North Water Polynya (NOW, Inuktitut: Sarvarjuaq; Kalaallisut:Pikialasorsuaq), Baffin Bay, is the largest polynya and one of the most productive regionsin the Arctic. This area of thin to absent sea ice is a critical moisturesource for local ice sheet sustenance and, coupled with the inflow ofnutrient-rich Arctic Surface Water, supports a diverse community of Arcticfauna and indigenous people. Although paleoceanographic records provideimportant insight into the NOW's past behavior, it is critical that webetter understand the modern functionality of paleoceanographic proxies. Inthis study, we analyzed lipid biomarkers, including algal highly branchedisoprenoids and sterols for sea ice extent and pelagic productivity andarchaeal glycerol dibiphytanyl glycerol tetraethers (GDGTs) for ocean temperature, in a set of modern surface sedimentsamples from within and around the NOW. In conjunction with previouslypublished datasets, our results show that all highly branched isoprenoidsexhibit strong correlations with each other and not with sterols, whichsuggests a spring or autumn sea ice diatom source for all highly branched isoprenoids (HBIs) rather than acombination of sea ice and open-water diatoms as seen elsewhere in theArctic. Sterols are also highly concentrated in the NOW and exhibitstatistically higher concentrations here compared to sites south of the NOW,consistent with the order of magnitude higher primary productivity observedwithin the NOW relative to surrounding waters in spring and summer months.Finally, our local temperature calibrations for GDGTs and OH-GDGTs reducethe uncertainty present in global temperature calibrations but alsoidentify some additional variables that may be important in controllingtheir local distribution, such as nitrate availability and dissolved oxygen.Collectively, our analyses provide new insight into the utility of theselipid biomarker proxies in high-latitude settings and will help provide arefined perspective on the past development of the NOW with theirapplication in downcore reconstructions. 

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4. Water Circulation Driven by Cold Fronts in the Wax Lake Delta (Louisiana, USA)

   https://doi.org/10.3390/jmse10030415  

   Zhang, Qian; Li, Chunyan; Huang, Wei; Lin, Jun; Hiatt, Matthew; Rivera-Monroy, Victor H. (March 2022, Journal of Marine Science and Engineering)

   Atmospheric cold fronts can periodically generate storm surges and affect sediment transport in the Northern Gulf of Mexico (NGOM). In this paper, we evaluate water circulation spatiotemporal patterns induced by six atmospheric cold front events in the Wax Lake Delta (WLD) in coastal Louisiana using the 3-D hydrodynamic model ECOM-si. Model simulations show that channelized and inter-distributary water flow is significantly impacted by cold fronts. Water volume transport throughout the deltaic channel network is not just constrained to the main channels but also occurs laterally across channels accounting for about a quarter of the total flow. Results show that a significant landward flow occurs across the delta prior to the frontal passage, resulting in a positive storm surge on the coast. The along-channel current velocity dominates while cross-channel water transport occurs at the southwest lobe during the post-frontal stage. Depending on local weather conditions, the cold-front-induced flushing event lasts for 1.7 to 7 days and can flush 32–76% of the total water mass out of the system, a greater range of variability than previous reports. The magnitude of water flushed out of the system is not necessarily dependent on the duration of the frontal events. An energy partitioning analysis shows that the relative importance of subtidal energy (10–45% of the total) and tidal energy (20–70%) varies substantially from station to station and is linked to the weather impact. It is important to note that within the WLD region, the weather-induced subtidal energy (46–66% of the total) is much greater than the diurnal tidal energy (13–25% of the total). The wind associated with cold fronts in winter is the main factor controlling water circulation in the WLD and is a major driver in the spatial configuration of the channel network and delta progradation rates. 

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5. Paleoclimatic implications of glacial fluctuations in the Sierra Nevada del Cocuy, northern Andes, Colombia, during the Lateglacial and Holocene

   https://doi.org/10.1016/j.quascirev.2025.109458  

   Herbert, Jordan N; Bromley, Gordon RM; Kelly, Meredith A; Doughty, Alice M; Ruiz-Carrascal, Daniel; Restrepo-Moreno, Sergio A; Londoño, Santiago Noriega; Galloway, Peter; Hidy, Alan J (September 2025, Quaternary Science Reviews)

   The reconstruction of former mountain glaciers from geomorphic mapping and cosmogenic-nuclide surface exposure dating provides a unique opportunity to infer patterns of past terrestrial climate variability. Tropical mountain glaciers are particularly valuable as there are comparatively few terrestrial climate proxies at equatorial latitudes relative to higher latitudes. As the single largest climate zone on Earth, the tropics play an outsized role in mediating global climate via the ocean-atmosphere transfer of latent heat and water vapor. Nonetheless, there remains a persistent gap in our understanding of how the tropics influenced – or were influenced by – the high-magnitude climate shifts of the Late Pleistocene, and whether this high-energy region simply responded to extratropical forcing or was itself a driver of global climatic change. To help address this knowledge gap, we analyzed geologic evidence for past glacial fluctuations in three adjacent valleys in the Sierra Nevada del Cocuy, the highest subrange of the Eastern Cordillera in the Colombian Andes, to provide a terrestrial record of atmospheric temperature during the latter part of Termination 1. Coupled with geomorphic mapping and paleo-snowline reconstructions, our beryllium-10 glacial chronology indicates that glaciers in the humid inner tropics underwent pronounced growth and gradual decay during the Antarctic Cold Reversal (14.5–12.8 ka) and Younger Dryas (12.8–11.7 ka) periods, respectively, following a trend that, according to directly dated moraine records from throughout both polar hemispheres, appears to have been global. While the specific mechanism(s) behind this large-scale behavior remains to be corroborated, we revisit the hypothesis that ocean atmosphere heat transfer and water vapor flux are key drivers of abrupt Lateglacial temperature fluctuations. Subsequent to the Lateglacial, deglaciation of the Sierra Nevada del Cocuy accelerated during the Early Holocene, a pattern also observed in other tropical glacier records. More recently, the magnitude of snowline rise and glacier retreat over the last two centuries supports the view that modern tropospheric warming is anomalously strong at least relative to the last ~16,000 years. 

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