Cosmogenic nuclide exposure age scatter records glacial history and processes in McMurdo Sound, Antarctica

IF 2.7 Q2 GEOCHEMISTRY & GEOPHYSICS
A. Christ, P. Bierman, J. Lamp, J. Schaefer, G. Winckler
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引用次数: 1

Abstract

Abstract. The preservation of cosmogenic nuclides that accumulated during periods of prior exposure but were not subsequently removed by erosion or radioactive decay complicates interpretation of exposure, erosion, and burial ages used for a variety of geomorphological applications. In glacial settings, cold-based, non-erosive glacier ice may fail to remove inventories of inherited nuclides in glacially transported material. As a result, individual exposure ages can vary widely across a single landform (e.g., moraine) and exceed the expected or true depositional age. The surface processes that contribute to inheritance remain poorly understood, thus limiting interpretations of cosmogenic nuclide datasets in glacial environments. Here, we present a compilation of new and previously published exposure ages of multiple lithologies in local Last Glacial Maximum (LGM) and older Pleistocene glacial sediments in the McMurdo Sound region of Antarctica. Unlike most Antarctic exposure chronologies, we are able to compare exposure ages of local LGM sediments directly against an independent radiocarbon chronology of fossil algae from the same sedimentary unit that brackets the age of the local LGM between 12.3 and 19.6 ka. Cosmogenic exposure ages vary by lithology, suggesting that bedrock source and surface processes prior to, during, and after glacial entrainment explain scatter. 10Be exposure ages of quartz in granite, sourced from the base of the stratigraphic section in the Transantarctic Mountains, are scattered but young, suggesting that clasts entrained by sub-glacial plucking can generate reasonable apparent exposure ages. 3He exposure ages of pyroxene in Ferrar Dolerite, which crops out above outlet glaciers in the Transantarctic Mountains, are older, which suggests that clasts initially exposed on cliff faces and glacially entrained by rock fall carry inherited nuclides. 3He exposure ages of olivine in basalt from local volcanic bedrock in the McMurdo Sound region contain many excessively old ages but also have a bimodal distribution with peak probabilities that slightly pre-date and post-date the local LGM; this suggests that glacial clasts from local bedrock record local landscape exposure. With the magnitude and geological processes contributing to age scatter in mind, we examine exposure ages of older glacial sediments deposited by the most extensive ice sheet to inundate McMurdo Sound during the Pleistocene. These results underscore how surface processes operating in the Transantarctic Mountains are expressed in the cosmogenic nuclide inventories held in Antarctic glacial sediments.
宇宙成因核素暴露年龄散射记录了南极洲麦克默多湾的冰川历史和过程
摘要宇宙形成核素在先前暴露期间积累,但随后没有被侵蚀或放射性衰变去除,这使得用于各种地貌学应用的暴露、侵蚀和埋藏年龄的解释变得复杂。在冰川环境中,以冷为基础的非侵蚀性冰川冰可能无法清除冰川运输物质中遗传核素的库存。因此,个体暴露年龄可能在单一地形(如冰碛)上差异很大,并超过预期或真实的沉积年龄。有助于遗传的地表过程仍然知之甚少,因此限制了对冰川环境中宇宙形成核素数据集的解释。本文对南极麦克默多湾地区末次盛冰期(Last Glacial Maximum, LGM)和更老更新世(old Pleistocene)冰川沉积物中多种岩性的最新和先前发表的暴露年龄进行了汇编。与大多数南极暴露年代学不同,我们能够直接将当地LGM沉积物的暴露年龄与来自同一沉积单元的化石藻类的独立放射性碳年代学进行比较,该年代学将当地LGM的年龄置于12.3 - 19.6 ka之间。宇宙成因暴露年龄因岩性而异,这表明基岩源和冰川夹带之前、期间和之后的地表过程解释了散射。来自横贯南极山脉地层剖面底部的花岗岩中石英的暴露年龄是分散的,但很年轻,这表明冰川下摘取所携带的碎屑可以产生合理的表观暴露年龄。横贯南极山脉出口冰川上方的费拉尔白云岩中辉石的暴露年龄更老,这表明最初暴露在悬崖表面并在冰川时期被岩崩夹带的碎屑携带遗传核素。③麦克默多湾地区当地火山基岩玄武岩中橄榄石的出露年龄包含许多过老的年龄,但也具有双峰分布,峰值概率略早于当地LGM,也略晚于当地LGM;这表明来自当地基岩的冰川碎屑记录了当地的景观暴露。考虑到规模和地质过程对年龄分散的影响,我们研究了更新世期间淹没麦克默多湾的最广泛冰盖沉积的较老冰川沉积物的暴露年龄。这些结果强调了南极横贯山脉的地表过程是如何在南极冰川沉积物中保存的宇宙成因核素清单中表达出来的。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Geochronology
Geochronology Earth and Planetary Sciences-Paleontology
CiteScore
6.60
自引率
0.00%
发文量
35
审稿时长
19 weeks
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