宇宙成因核素风化偏差:剥蚀和风化速率测量的修正和潜力

IF 2.7 Q2 GEOCHEMISTRY & GEOPHYSICS
Richard F. Ott, S. Gallen, D. Granger
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引用次数: 6

摘要

摘要宇宙形成的放射性核素(crn)是衍生百万年至千年时间尺度剥蚀率的标准工具;然而,已有研究表明,在某些环境下,化学风化作用可以使crn作为景观剥蚀的代表。目前,研究crn风化偏倚的研究主要集中在长英质岩性中大部分不溶性的靶矿物石英上。本文研究了不同风化条件下可溶性和不可溶性目标矿物对crn积累的响应。我们假设一个简单的盒子模型,其中基岩以恒定的速率转化为混合良好的风化层,剥蚀发生在风化层或沿风化层-基岩界面的风化层中,这在碳酸盐岩基岩中很常见。我们表明,与没有风化作用的情况相比,沿风化岩-基岩界面的风化作用增加了CRN浓度,以及如何使用独立推导的风化速率或程度来纠正这种偏差。如果风化作用集中在风化层内,则不溶性目标矿物比可溶性目标矿物具有更长的风化层停留时间和更高的核素浓度。这种偏差可以通过对不同溶解度的矿物进行配对核素测量,结合基岩或风化层矿物学知识来确定和纠正,从而得出剥蚀和长期风化速率。同样,如果有风化速率和成分数据,可对可溶或不可溶矿物的单核素测量值进行校正,以确定剥蚀速率。我们的模型强调,对于可溶性目标矿物,核素积累和剥蚀之间的关系不是单调的。我们利用这一认识来绘制风化层质量、风化和剥蚀率的条件图,在这些条件下,宇宙形成核素的风化校正变得大而模糊,以及识别偏差大多可以忽略不计的环境,CRN浓度可靠地反映景观剥蚀。我们强调了如何从可溶性目标矿物中测量crn,再加上基岩和风化层矿物学,可以帮助扩大景观的范围,从而获得百年至千年时间尺度的剥蚀和风化速率。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Cosmogenic nuclide weathering biases: corrections and potential for denudation and weathering rate measurements
Abstract. Cosmogenic radionuclides (CRNs) are the standard tool to derive centennial-to-millennial timescale denudation rates; however, it has been demonstrated that chemical weathering in some settings can bias CRNs as a proxy for landscape denudation. Currently, studies investigating CRN weathering biases have mostly focused on the largely insoluble target mineral quartz in felsic lithologies. Here, we examine the response of CRN build-up for both soluble and insoluble target minerals under different weathering scenarios. We assume a simple box model in which bedrock is converted to a well-mixed regolith at a constant rate, and denudation occurs by regolith erosion and weathering either in the regolith or along the regolith–bedrock interface, as is common in carbonate bedrock. We show that weathering along the regolith–bedrock interface increases CRN concentrations compared to a no-weathering case and how independently derived weathering rates or degrees can be used to correct for this bias. If weathering is concentrated within the regolith, insoluble target minerals will have a longer regolith residence time and higher nuclide concentration than soluble target minerals. This bias can be identified and corrected using paired-nuclide measurements of minerals with different solubility coupled with knowledge of either the bedrock or regolith mineralogy to derive denudation and long-term weathering rates. Similarly, single-nuclide measurements on soluble or insoluble minerals can be corrected to determine denudation rates if a weathering rate and compositional data are available. Our model highlights that for soluble target minerals, the relationship between nuclide accumulation and denudation is not monotonic. We use this understanding to map the conditions of regolith mass, weathering, and denudation rates at which weathering corrections for cosmogenic nuclides become large and ambiguous, as well as identify environments in which the bias is mostly negligible and CRN concentrations reliably reflect landscape denudation. We highlight how measurements of CRNs from soluble target minerals, coupled with bedrock and regolith mineralogy, can help to expand the range of landscapes for which centennial-to-millennial timescale denudation and weathering rates can be obtained.
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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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