Aqueous geochemistry of the Thermopolis hydrothermal system, southern Bighorn Basin, Wyoming, U.S.A.

Q3 Earth and Planetary Sciences

Rocky Mountain Geology Pub Date : 2014-03-01 DOI:10.2113/GSROCKY.49.1.1

J. Kaszuba, K. Sims, Allison R. Pluda

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引用次数: 1

Abstract

The Thermopolis hydrothermal system is located in the southern portion of the Bighorn Basin, in and around the town of Thermopolis, in northwest Wyoming. It is the largest hydrothermal system in Wyoming outside of Yellowstone National Park. The system includes hot springs, travertine deposits, and thermal wells. Published models for the hydrothermal system propose the Owl Creek Mountains as the recharge zone, simple conductive heating at depth, and resurfacing of thermal waters up the Thermopolis Anticline. The geochemistry of the thermal waters of three active hot springs—Big Spring, White Sulphur Spring, and Teepee Fountain—is similar in composition and characteristic of carbonate or carbonate-bearing siliciclastic aquifers. Previous studies of the Thermopolis hydrothermal system postulate that the thermal waters are a mixture of waters from Paleozoic formations. Major element geochemical analyses available for waters from these formations are not of sufficient quality to determine whether the thermal waters are a mixture of the Paleozoic aquifers. In the time frame of this study (one year), the geochemistry of all three springs was constant through all four seasons, spanning spring snowmelt and recharge as well as late-summer and fall dryness. This relationship is consistent with a deep source not influenced by shallow, local hydrogeology. Anomalies are evident in the historic data set for the geochemistry of Big Spring. We speculate that anomalies occurring between 1906 and 1926 suggest mixing of source waters of Big Spring with waters from a siliciclastic formation, and that anomalies occurring between 1926 and 1933 suggest mixing with waters from a formation containing gypsum or anhydrite. Decreased concentrations measured in our study—relative to concentrations measured between 1933 and 1976—may reflect mixing of thermal waters with more dilute waters. Current data are not sufficient to rigorously test these suggestions, and events of sufficient scale taking place in these timeframes have not been identified.

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美国怀俄明州大角盆地南部Thermopolis热液系统的水地球化学特征

Thermopolis热液系统位于大角盆地的南部，位于怀俄明州西北部的Thermopolis镇及其周围。它是怀俄明州除黄石国家公园外最大的热液系统。该系统包括温泉、石灰华矿床和热水井。已发表的热液系统模型提出Owl Creek Mountains是补给区，深层简单的导电加热，以及热城背斜上的热水重新表面。大泉、白硫泉和圆锥形喷泉三个活跃温泉的热水地球化学成分和特征与碳酸盐或含碳酸盐的硅橡胶含水层相似。以前对热城热液系统的研究假设热液是古生代地层水的混合物。对这些地层的水进行的主要元素地球化学分析，其质量不足以确定热水是否是古生代含水层的混合物。在本研究的时间框架内(一年)，所有三个泉的地球化学在所有四个季节都是恒定的，包括春季融雪和补给以及夏末和秋季干旱。这种关系与不受浅层局部水文地质影响的深层源相一致。在大泉的地球化学历史数据集中，异常是明显的。我们推测，在1906年至1926年之间发生的异常表明，大泉的水源与来自硅质地层的水混合，而在1926年至1933年之间发生的异常表明，与来自含石膏或硬石膏地层的水混合。我们研究中测量到的浓度下降——相对于1933年至1976年之间测量的浓度——可能反映了热水与更稀的水的混合。目前的数据不足以严格检验这些建议，而且在这些时间范围内发生的足够规模的事件尚未确定。

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来源期刊

Rocky Mountain Geology Earth and Planetary Sciences-Geology

CiteScore

1.10

自引率

0.00%

发文量

期刊介绍： Rocky Mountain Geology (formerly Contributions to Geology) is published twice yearly by the Department of Geology and Geophysics at the University of Wyoming. The focus of the journal is regional geology and paleontology of the Rocky Mountains and adjacent areas of western North America. This high-impact, scholarly journal, is an important resource for professional earth scientists. The high-quality, refereed articles report original research by top specialists in all aspects of geology and paleontology in the greater Rocky Mountain region.