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1. Tectonic, hydrogeologic, and climatic controls on Late Holocene dune formation, China Lake basin, Indian Wells Valley, California, USA

   https://doi.org/10.1017/qua.2021.62  

   Lancaster, Nicholas; Bacon, Steven N.; Bullard, Thomas F.; Neudorf, Christina M.; Keen-Zebert, Amanda K.; Decker, David L.; Boggs, Matthew L. (March 2022, Quaternary Research)

   Abstract Analysis of patterns of faulting and hydrogeology, stratigraphic and sedimentologic studies, and luminescence dating of aeolian deposits in China Lake basin provide new perspectives on the origins and development of Late Holocene dunes and sand ramps in the seismically active Indian Wells Valley of eastern California. Aeolian dune and sand sheet deposits were sourced from alluvial material derived from granitic rocks of the south-eastern Sierra Nevada and are concentrated in areas with sand-stabilizing phreatophyte vegetation influenced by high groundwater levels along the active oblique-normal Little Lake and Paxton Ranch faults, which locally form barriers to groundwater flow. Three episodes of sand accumulation are recognized (2.1 ± 0.1 to 2.0 ± 0.1 ka, 1.8 ± 0.2 to 1.6 ± 0.2 ka, and 1.2 ± 0.1 to 0.9 ± 0.1 ka) during conditions in which sediment supplied to the basin during periods of enhanced rainfall and runoff was subsequently reworked by wind into dunes and sand ramps at the transition to more arid periods. Understanding the role tectonics plays in influencing the hydrogeology of seismically active lake basins provides insights to accurately interpret landscape evolution and any inferences made on past hydroclimate variability in a region. 

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2. Moisture availability and groundwater recharge paced by orbital forcing over the past 750,000 years in the southwestern USA

   https://doi.org/10.1038/s43247-024-01550-0  

   Steidle, Simon_D; Wendt, Kathleen_A; Dublyansky, Yuri; Edwards, R_Lawrence; Li, Xianglei; McClure, Gracelyn; Moseley, Gina_E; Spötl, Christoph (July 2024, Communications Earth & Environment)

   Abstract Quaternary climate changes are driven in part by variations in the distribution and strength of insolation due to orbital parameters. Continental climate variability is well documented for the most recent glacial-interglacial cycles, yet few records extend further back in time. Such records are critically needed to comprehensively assess the entire spectrum of natural climate variability against the backdrop of anthropogenic warming. Here, we apply uranium isotope geochronology to calcite deposits to date groundwater-table changes in Devils Hole cave, Nevada. The deposits record multi-meter groundwater-table fluctuations over the last 750,000 years, reflecting the long-term evolution of hydroclimate in this presently arid region. During periods between glacial or interglacial extremes, the water table responded sensitively to variations in 65°N summer insolation, likely caused by the increasing extent of North American ice sheets during cold period, which steered moisture-laden trajectories towards the southwestern USA. These orbitally-driven hydroclimatic changes are superimposed on a tectonically-driven long-term decline in the regional groundwater table observed prior to 438,000 ± 14,000 years ago. 

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3. East African Climate During a Major Turnover in Mammal Species between 400 and 500 thousand years ago

   Johnson, T.; Ramirez, B.; Salacup, J.; Castañeda, I.S. (October 2022, Abstracts Geological Society of America)

   Roughly 85% of mammalian herbivore species in southern Kenya were replaced by smaller, more adaptable species at some time between 400,000 years ago (400ka) and 500 ka. While this major taxonomic turnover has been attributed to a shift to more a more arid and variable climate and tectonic activity, we wondered if a particularly abrupt shift, a “tipping point,” in climate at some time between 400 and 500 ka was the cause. We analyzed the highest resolution paleoclimate record available in East Africa, Lake Malawi drill core MAL05-1B, for organic geochemical proxies, including branched glycerol dialkyl glycerol tetraethers (GDGTs) and leaf wax deuterium isotopic records to develop the temperature and precipitation history, respectively, between 600 and 200 ka. Results show an abrupt temperature increase of ~6°C occurring in less than 3000 years during Glacial Termination V, which is the Marine Isotope Stage (MIS) 12 to MIS 11 transition at ~430 ka. Surprisingly, even more intense warming occurred during Glacial Termination VI around 510 ka. Notably, these deglacial warmings coincide with enriched leaf wax deuterium isotopic values suggesting a shift to more arid conditions in interglacials MIS 13 and 11 than in glacials MIS 14 and 12, respectively. These changes from cold/wet glacials to warm/dry interglacials contrast with the cool/dry pattern of the Last Glacial Maximum (LGM) in East Africa that transitioned to a warm/wet Holocene. We propose that the major warming and drying during Termination V in the Malawi basin represents a significant abrupt change that impacted much of eastern Africa around 430 ka and was a likely driver of the major faunal turnover noted in the region. 

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4. Updated Stratigraphic Mapping Reveals Insights Into the Late Pleistocene Evolutionary History of the Virginia Eastern Shore, US Mid-Atlantic Coast

   https://doi.org/10.29041/strat.22.2.02  

   Cahoon, Kayla M; Hein, Christopher J; Fenster, Michael; Clarke, Cameron; Ramsey, Kelvin W (June 2025, Stratigraphy)

   Contradictory interpretations of upper Pleistocene (120–40 ka) sedimentary deposits along the US Mid-Atlantic Coast have hindered the development of a reliable regional sea-level curve for the last glacial cycle. This study presents new and compiled sediment cores, ground-penetrating radar, topographic data, aerial imagery, and limited geochronology from geologic units emplaced along the ocean-facing side of the Virginia Eastern Shore during mid- and late-Pleistocene periods of higher-than-present relative sea level: the Accomack Member (Omar Formation), the Butlers Bluff Member (Nassawadox Formation), the Joynes Neck Sand, and the Wachapreague Formation. Minor lithologic and morphologic updates are presented for the MIS 5e/5c Butlers Bluff Member, which is interpreted as a southward-prograding spit emplaced atop penecontemporaneous shoreface sediments or older transgressive sediments which fill the Exmore Paleochannel. The Joynes Neck Sand is reinterpreted as a coastal lag deposit, correlated with the Ironshire Formation in Maryland and Delaware, likely emplaced during MIS 5c. The Wachapreague Formation is determined to be a composite unit composed of two newly mapped members—the Locustville and Upshur Neck—which differ in lithology, internal architecture, and surficial morphology. The older and western Locustville Member (MIS 5a) is characterized by progradational beach and foredune ridges built atop transgressive shoreface and backbarrier deposits, and is correlated with the Sinepuxent Formation in Maryland and Delaware. The younger and eastern Upshur Neck Member of the Wachapreague Formation (late MIS 5a) is distinguished by surficial recurved ridges and preserved washover, dune, and channel-fill structures associated with spit growth atop shoreface deposits. These findings indicate that the Wachapreague Formation was constructed during two sequential highstands: an initial phase of sea-level rise and then fall allowed for deposition of the Locustville Member as a transgressive-highstand-regressive barrier system; and, following a period of lower-than-present sea level, a later highstand resulted in partial erosion of the easternmost Locustville and growth of the Upshur Neck Member. Finally, we update earlier descriptions of an aeolian sand sheet, likely deposited during MIS 3c, that discontinuously overlies most of the east-central Virginia Eastern Shore. Together, these findings update interpretations of the depositional history of the southern Delmarva Peninsula, and allow for future refinement of the sea-level history of the last interglacial-to-glacial period along the mid-field US Mid-Atlantic coast. 

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5. Polar bear's range dynamics and survival in the Holocene

   https://doi.org/10.1016/j.quascirev.2023.108277  

   Seppä, Heikki; Seidenkrantz, Marit-Solveig; Caissie, Beth; Macias-Fauria, Marc (October 2023, Quaternary Science Reviews)

   Polar bear (Ursus maritimus) is the apex predator of the Arctic, largely dependent on sea-ice. The expected disappearance of the ice cover of the Arctic seas by the mid 21st century is predicted to cause a dramatic decrease in the global range and population size of the species. To place this scenario against the backdrop of past distribution changes and their causes, we use a fossil dataset to investigate the polar bear’s past distribution dynamics during the Late Glacial and the Holocene. Fossil results indicate that during the last deglaciation, polar bears were present at the southwestern margin of the Scandinavian Ice Sheet, surviving until the earliest Holocene. There are no Arctic polar bear findings from 8,000-6,000 years ago (8-6 ka), the Holocene’s warmest period. However, fossils that date from 8-9 ka and 5-6 ka suggest that the species likely survived this period in cold refugia located near the East Siberian Sea, northern Greenland and the Canadian Archipelago. Polar bear range expansion is documented by an increase in fossils during the last 4,000 years in tandem with cooling climate and expanding Arctic sea ice. The results document changes in polar bear’s distribution in response to Late Glacial and Holocene Arctic temperature and sea ice trends. 

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