A New Map of Pleistocene Proglacial Lake Tight Based on GIS Modeling and Analysis

Q4 Multidisciplinary

Ohio Journal of Sciences Pub Date : 2018-12-05 DOI:10.18061/OJS.V118I2.6548

James L. Erjavec

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引用次数: 1

Abstract

Glacial-age Lake Tight was first mapped by John F. Wolfe in 1942. Wolfe compiled his map from photographs of 50 USGS topographic maps, and used the 900-foot contour to delineate its shoreline. An estimate, as reported by Hansen in 1987, suggested an area of approximately 18,130 km2 (7,000 mi2) for the lake. Using a geographic information system (GIS) environment, an updated map of Lake Tight was developed employing the 275-meter (902-foot) elevation contour. Calculations now suggest the area of Lake Tight was 43 percent larger or approximately 26,000 km2 (10,040 mi2) and the volume approximately 1,120 km3 (268 mi3). The reconstruction of Lake Tight in a GIS creates a spatial analysis platform that can support research on the origin and development of the lake, the geologic processes that occurred as a consequence of the advance of the pre-Illinoian ice, and the origin of the Ohio River. The development of the upper Ohio Valley during the Quaternary Period remains one of the outstanding problems in North American geology. The details of the transition from the Teays River to Lake Tight, and from Lake Tight to the Ohio River, are poorly understood despite more than 100-years passing since the first significant study of those changes. A refined understanding of the area and depth of Lake Tight is essential but is complicated by fundamental unknowns—such as the location of the pre-Illinoian ice margin and the extent and consequence of isostatic flexure of the lithosphere due to ice-loading and lake-loading. Given the assumptions required for the model, the accuracy of both the raster data and the 1942 topographic maps, and the paucity of essential field data, mapping the lake shoreline at the widely cited 274.32-meter (900-foot) contour would not provide increased verifiable accuracy.

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基于GIS建模与分析的更新世前冰期湖泊分布图

冰河时代的斯特湖最早是由约翰·f·沃尔夫在1942年绘制的。沃尔夫根据50张美国地质勘探局地形图的照片编制了他的地图，并用900英尺的等高线划定了它的海岸线。汉森在1987年的报告中估计，该湖的面积约为18,130平方公里(7,000平方英里)。利用地理信息系统(GIS)环境，采用275米(902英尺)的高程等高线绘制了一幅最新的斯泰特湖地图。现在的计算表明，斯泰特湖的面积要大43%，约为26000平方公里(10040平方英里)，体积约为1120平方公里(268平方英里)。在GIS中重建斯泰特湖创建了一个空间分析平台，可以支持对湖泊的起源和发展、前伊利诺斯州冰的推进所导致的地质过程以及俄亥俄河起源的研究。上俄亥俄河谷第四纪的发育一直是北美地质研究的突出问题之一。尽管对这些变化的第一次重要研究已经过去了100多年，但人们对从Teays河到Tight湖以及从Tight湖到俄亥俄河的转变的细节知之甚少。对斯泰特湖的面积和深度的精确了解是必不可少的，但由于一些基本的未知因素，如前伊利诺斯纪冰缘的位置，以及由冰和湖负载引起的岩石圈均衡弯曲的程度和后果，使研究变得复杂。考虑到模型所需的假设，栅格数据和1942年地形图的准确性，以及基本野外数据的缺乏，在被广泛引用的274.32米(900英尺)等高线上绘制湖岸线不会提供更高的可验证精度。

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

Ohio Journal of Sciences Multidisciplinary-Multidisciplinary

CiteScore

0.30

自引率

0.00%

发文量

期刊介绍： Published quarterly, plus the Annual Meeting Program Abstracts, The Ohio Journal of Science is the official publication of the Academy. The Journal publishes peer-reviewed, refereed papers contributing original knowledge to science, engineering, technology, education and their applications. The Journal is indexed and abstracted by many of the world"s leading indexing and abstracting services including State Academies of Science Abstracts which indexes the past 50 years of The Ohio Journal of Science.