由构造、岩性和气候驱动因素造成的阿拉斯加德纳利异常高地势

IF 4.8 1区 地球科学 Q1 GEOCHEMISTRY & GEOPHYSICS
A. Matmon , P.J. Haeussler , M. Loso , ASTER Team
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引用次数: 0

摘要

我们对位于阿拉斯加州阿拉斯加山脉、北美最高山峰(海拔 6190 米)德纳利峰的异常高地势增长进行了评估。迪纳利峰比周围大多数山峰高出 3000 米。它位于活跃的迪纳利断层系统中一个 19° 的限制性弯曲内,该断层系统以大约 7 毫米/年的速度移动,为持续的岩石隆起提供了构造和结构驱动力。迪纳利周围的高地势部分也是由于其花岗岩岩石类型和相对于邻近的玄武岩较低的断裂密度。在这里,我们展示了高海拔地区独特的气候条件也有助于地貌的增长。我们研究了以下样本中的 10Be 浓度:1)海拔 3500 米至 5200 米之间、未受近期冰川侵蚀影响的三个新的砾石样本;2)之前发表的、来自卡希尔特纳冰川侧壁 2400 米至 2800 米处的样本;3)之前发表的、来自卡希尔特纳冰川侧壁 2400 米至 2800 米处的样本、3) 此前公布的从卡希尔特纳冰川沿线海拔 500 至 1400 米的内侧冰碛采集的样本数据;以及 4) 此前公布的从卡希尔特纳河沿线海拔 200 米的冲积层采集的样本数据。这些样本构成了一个垂直延伸达 5000 米的横断面,这些数据证实了侵蚀率随着海拔的升高而降低,并促进了地形的增长。根据计算,三个新的高海拔样本的侵蚀速率分别为:5200 海拔 4.6 ± 0.6 毫米/千卡,4000 海拔 28.6 ± 3.7 毫米/千卡,3500 海拔 38±5 毫米/千卡。卡希尔特纳冰川侧壁中等海拔地区的侵蚀率介于 160 至 327 毫米/千卡之间。沿中间冰碛推断的侵蚀率介于 140 至 537 毫米/千卡之间,而根据冰川下方河流中的沉积物计算出的全流域侵蚀率介于 450 至 896 毫米/千卡之间。这些侵蚀速率的差异可在 1-10 Ma 内造成 3 km 的地形起伏,完全符合德纳利在过去 ∼6 Ma 岩石隆起和掘起的估计增长期。从 2130 到 5550 masl 的 5 个地点的气象数据显示,海拔 4000 masl 以上的温度很少超过冰点,这表明霜冻风化目前在高海拔地区的侵蚀作用已经减弱。这种温度与侵蚀相关性的直接影响就是地势的上升。这是第一项直接测量高海拔地区在相对没有霜冻风化的情况下侵蚀率显著下降的研究。研究结果凸显了岩石类型、冰川侵蚀和永久性零下温度对侵蚀率的综合影响。这些数据与活动断层相结合,解释了阿拉斯加山脉南侧在过去 100 ka 年间地势上升的原因。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Anomalously high relief on Denali, Alaska, caused by tectonic, lithologic, and climatic drivers

We assess the growth of anomalously high relief on Denali, located in the Alaska Range, Alaska, and the tallest mountain in North America (6190 masl). Denali is 3000 m taller than most surrounding peaks. It lies inside a 19° restraining bend in the active Denali fault system that is moving at about 7 mm/yr, providing a tectonic and structural driver for ongoing rock uplift. High relief around Denali is also due, in part, to its granitic rock type and low fracture density relative to adjacent metasediments. Here we show that unique climatic conditions at high elevations also contribute to the growth of relief. We examine 10Be concentrations in 1) three new gravel samples between 3500 and 5200 m elevation from sites unaffected by recent glacial erosion, 2) previously published samples from a sidewall of the Kahiltna Glacier from 2400 to 2800 masl, 3) previously published data for samples collected from medial moraines along the length of the Kahiltna Glacier from ∼500 to 1400 masl, and 4) previously published data for alluvial samples collected along the Kahiltna River at an elevation of ∼200 masl. These samples constitute a transect extending >5000 vertical meters, and the data establish that erosion rates decrease with elevation and contribute to the growth of relief. Erosion rates for the three new high-elevation samples are calculated to 4.6 ± 0.6 mm/ka at 5200 masl, 28.6 ± 3.7 mm/ka at 4000 masl, and 38±5 mm/ka at 3500 masl. Erosion rates at intermediate elevations, on the sidewall of the Kahiltna Glacier, range between 160 and 327 mm/ka. Along the medial moraines inferred erosion rates range between 140 and 537 mm/ka, and basin-wide erosion rates calculated from sediments in the river below the glacier range between 450 and 896 mm/ka. These differences in erosion rates can create relief of 3 km within 1–10 Ma, well within the estimated period of increase in rock uplift and exhumation on Denali over the last ∼6 Ma. Meteorological data from 2130 to 5550 masl at 5 sites show temperatures rarely exceed freezing above 4000 masl elevation, indicating that frost weathering currently plays a diminished role in erosion at high elevations. The immediate implication of this temperature and erosional correlation is an increase in relief. This is the first study to directly measure a significant decrease in erosion rates at high elevations in the relative absence of frost weathering. The results highlight the combined influence of rock type, glacial erosion, and permanent sub-zero temperatures on erosion rates. In combination with active faulting, the data explain the resultant increase in relief along the southern side of the Alaska Range over the past 100 ka.

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来源期刊
Earth and Planetary Science Letters
Earth and Planetary Science Letters 地学-地球化学与地球物理
CiteScore
10.30
自引率
5.70%
发文量
475
审稿时长
2.8 months
期刊介绍: Earth and Planetary Science Letters (EPSL) is a leading journal for researchers across the entire Earth and planetary sciences community. It publishes concise, exciting, high-impact articles ("Letters") of broad interest. Its focus is on physical and chemical processes, the evolution and general properties of the Earth and planets - from their deep interiors to their atmospheres. EPSL also includes a Frontiers section, featuring invited high-profile synthesis articles by leading experts on timely topics to bring cutting-edge research to the wider community.
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