美国加州圣安地列斯断层系统Mission Creek滨带冲积扇沉积物的氯-36∕铍-10埋藏年代测定

IF 2.7 Q2 GEOCHEMISTRY & GEOPHYSICS
G. Balco, K. Blisniuk, A. Hidy
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引用次数: 4

摘要

摘要我们利用河流搬运的花岗岩类碎屑中的36cl -in- k长石∕10be -in-石英对,应用宇宙成因-核素埋藏测年技术,确定了南加州圣安德烈亚斯断层的Mission Creek滨带冲积沉积物的年代。由于36Cl和10Be的半衰期与常用的26Al∕10Be对的半衰期差异较大,36Cl∕10Be的埋藏定年应适用于约0.2 ~ 0.5 Ma的沉积物,而用26Al∕10Be对的年龄太小,不能准确定年,而对于一般的中晚更新世沉积物应更为精确。然而,使用36Cl∕10Be对比较复杂,因为36Cl∕10Be的生产比例随每个样品的化学成分而变化。我们使用目前暴露在地表的花岗闪长岩样品中的36Cl∕10Be测量值来验证该岩性中36Cl∕10Be生产比的计算结果,然后我们应用该信息来确定相同岩性的冲积碎屑的埋藏年龄。这一特殊的区域为埋藏年代测定带来了额外的障碍(这并不局限于36Cl / 10Be对,但适用于任何地方),因为大多数埋藏的冲积碎屑来自圣贝纳迪诺山脉极快的侵蚀部分,相应的核素浓度极低,其中大部分很可能来自成核(36Cl)和埋藏后的产物。尽管这妨碍了许多碎屑的准确埋藏年代测定,但来自低侵蚀速率源区的具有较高核素浓度的地表和地下样品的数据表明,上卡贝逊组冲积层的年龄为260 ka。这与地层年龄限制以及对长期断层滑动率的独立估计是一致的,并突出了36Cl∕10Be对在上更新世和中更新世碎屑沉积物定年方面的潜在作用。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Chlorine-36∕beryllium-10 burial dating of alluvial fan sediments associated with the Mission Creek strand of the San Andreas Fault system, California, USA
Abstract. We apply cosmogenic-nuclide burial dating using the 36Cl-in-K-feldspar∕10Be-in-quartz pair in fluvially transported granitoid clasts to determine the age of alluvial sediment displaced by the Mission Creek strand of the San Andreas Fault in southern California. Because the half-lives of 36Cl and 10Be are more different than those of the commonly used 26Al∕10Be pair, 36Cl∕10Be burial dating should be applicable to sediments in the range ca. 0.2–0.5 Ma, which is too young to be accurately dated with the 26Al∕10Be pair, and should be more precise for Middle and Late Pleistocene sediments in general. However, using the 36Cl∕10Be pair is more complex because the 36Cl∕10Be production ratio varies with the chemical composition of each sample. We use 36Cl∕10Be measurements in samples of granodiorite exposed at the surface at present to validate calculations of the 36Cl∕10Be production ratio in this lithology, and then we apply this information to determine the burial age of alluvial clasts of the same lithology. This particular field area presents the additional obstacle to burial dating (which is not specific to the 36Cl∕10Be pair, but would apply to any) that most buried alluvial clasts are derived from extremely rapidly eroding parts of the San Bernardino Mountains and have correspondingly extremely low nuclide concentrations, the majority of which most likely derive from nucleogenic (for 36Cl) and post-burial production. Although this precludes accurate burial dating of many clasts, data from surface and subsurface samples with higher nuclide concentrations, originating from lower-erosion-rate source areas, show that the age of upper Cabezon Formation alluvium is 260 ka. This is consistent with stratigraphic age constraints as well as independent estimates of long-term fault slip rates, and it highlights the potential usefulness of the 36Cl∕10Be pair for dating Upper and Middle Pleistocene clastic sediments.
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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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