新的年代制约因素揭示了美国纽约西部最后一次脱冰期沉积数千年后冰碛的稳定情况

IF 2.7 Q2 GEOCHEMISTRY & GEOPHYSICS
K. Prince, J. Briner, C. Walcott, Brooke M. Chase, Andrew L Kozlowski, T. Rittenour, Erica P. Yang
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引用次数: 0

摘要

摘要纽约州西部劳伦特冰原最后一次脱冰期的时间很难确定。由于该地区缺乏直接的年代学资料,因此有一种假设认为,劳伦特冰原在纽约州西部末次冰川极盛时期的末端位置重新推进到 13 ka ∼ 13 ka,这对长期以来的数据集提出了挑战。针对这一假设,我们利用冰碛坑沉积物岩芯中的放射性碳年龄,并辅以冰接触三角洲顶床的两个光激发发光年龄,获得了肯特冰碛(末端)和陡崖湖冰碛(第一次大退缩)的新年表。这两个光激发发光年龄将肯特(终点)位置的年代分别定为 19.8 ± 2.6 ka 年和 20.6 ± 2.9 ka 年。在沉积岩芯中,有沉积学证据表明在盆地形成过程中地貌不稳定;我们岩芯中最低沉积物的放射性碳年龄不按地层顺序排列,其年代为 19 350-19 600 至 14 050-14 850 卡(公元前)。我们将这些年龄解释为冰原后退的松散的最小限制条件。我们最古老的放射性碳年龄为公元前 19 350-19 600 年--来自一个撕裂碎屑--表明当时没有冰。在最底层沉积物之上是富含有机质的淤泥和按地层顺序排列的放射性碳年龄。我们将这些富含有机质沉积物中的最低年龄解释为水壶盆地形成的最低限制条件。从肯特碛和陡崖湖碛上富含有机质的沉积物中得出的最低放射性碳年龄为公元前 15 000-15 400 年至公元前 13 600-14 000 年。我们将光学激发发光年龄与水壶盆地形成之间的 5 千年滞后解释为冰盖冰碛中持续埋藏冰的结果,直到 15 至 14 千年。与海因里希期 1 相关的寒冷条件可能使冰壳冰碛得以存活到 15 ka 之后,反过来,博林期(14.7-14.1 ka)的气候改善可能启动了地貌的稳定。这一模型有可能调和了支持重新前进假说的沉积学和年代学证据,而重新前进假说可能是博林-阿勒罗德时期(14.7-13 ka)冰碛不稳定和沉积物移动的结果。未来工作的年龄控制应侧重于不依赖于当地气候的特征。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
New age constraints reveal moraine stabilization thousands of years after deposition during the last deglaciation of western New York, USA
Abstract. The timing of the last deglaciation of the Laurentide Ice Sheet in western New York is poorly constrained. The lack of direct chronology in the region has led to a hypothesis that the Laurentide Ice Sheet re-advanced to near its Last Glacial Maximum terminal position in western New York at ∼ 13 ka, which challenges long-standing datasets. To address this hypothesis, we obtained new chronology from the Kent (terminal) and Lake Escarpment (first major recessional) moraines using radiocarbon ages in sediment cores from moraine kettles supplemented with two optically stimulated luminescence ages from topset beds in an ice-contact delta. The two optically stimulated luminescence ages date the Kent (terminal) position to 19.8 ± 2.6 and 20.6 ± 2.9 ka. Within the sediment cores, there is sedimentological evidence of an unstable landscape during basin formation; radiocarbon ages from the lowest sediments in our cores are not in stratigraphic order and date from 19 350–19 600 to 14 050–14 850 cal BP. We interpret these ages as loosely minimum-limiting constraints on ice sheet retreat. Our oldest radiocarbon age of 19 350–19 600 cal BP – from a rip-up clast – suggests ice-free conditions at that time. Above the lowest sediments there is organic-rich silt and radiocarbon ages in stratigraphic order. We interpret the lowest ages in these organic-rich sediments as minimum-limiting constraints on kettle basin formation. The lowest radiocarbon ages from organic-rich sediments from sites on both Kent and Lake Escarpment moraines range from 15 000–15 400 to 13 600–14 000 cal BP. We interpret the 5 kyr lag between the optically stimulated luminescence ages and kettle basin formation as the result of persistent buried ice in ice-cored moraines until ∼ 15 to 14 ka. The cold conditions associated with Heinrich Stadial 1 may have enabled the survival of ice-cored moraines until after 15 ka, and, in turn, climate amelioration during the Bølling period (14.7–14.1 ka) may have initiated landscape stabilization. This model potentially reconciles the sedimentological and chronological evidence underpinning the re-advance hypothesis, which instead could be the result of moraine instability and sediment mobilization during the Bølling–Allerød periods (14.7–13 ka). Age control for future work should focus on features that are not dependent on local climate.
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Geochronology
Geochronology Earth and Planetary Sciences-Paleontology
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