Donbas geoelectrical structure

IF 0.6 Q4 GEOCHEMISTRY & GEOPHYSICS
I. Rokityansky, A. Tereshyn
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引用次数: 1

Abstract

The Donbas was formed as the result of Late Devonian rifting of the East European craton. During the Carboniferous, the subsidence of the basin and sedimentation were at their maximum, and a 15-kilometer stratum of Carboniferous deposits formed in the Donbas. The total thickness of the deposits reaches more than 20 km. The next important event was folding, which occurred in the Late Triassic — Early Jurassic and Late Cretaceous — Early Tertiary. The inversion lifted the upper part of the folded Donbas and subsequent erosion exposed the Carboniferous coal-bearing strata on the surface of the earth. Deep electrical conductivity was studied by the methods of magnetovariational profiling (MVP) and magnetotelluric sounding (MTS). The first large survey (13 long-period MTS sites and 32 MTS points) was carried out in 1986; in 1988 another 30 MTS were performed. In 2012-2013, a profile of 15 MVP-MTS sites was made with modern instruments that allow obtaining more accurate results. The data interpretation yields the following conclusions. The intense Donbass electrical conductivity anomaly (DAE) runs along the main anticline of the folded Donbass. In the northwest, it continues in the DDD, in the southeast — on the Karpinsky swell. DAE parameters obtained by the MVP method: Based on the frequency response of the anomalous field, the total longitudinal conductance G = (8±2)×108S×m was estimated. Profile graphs of the anomalous field of geomagnetic variations give an estimate of the maximum possible depth of the anomalous currents center hmax.c.curr, which depends on the variations period. For DAE at the maximum frequency response Т0≈3600 s, it turns out to be equal to hmax.c.curr=18±2 km. The upper edge of the anomaly is estimated from MTS data. Most of the available 70 MTS ρк curves begin at periods of 0.1—1 s from approximately the same level of 15 Ohm·m±half an order of magnitude. This means that in the Donbass, the rocks of the upper approximately half-kilometer layer have, as a rule, electrical resistivity in the range of 5—50 Ohm·m. Deeper, the resistivity can increase to hundreds and thousands of Ohm·m or decrease to units or fractions of Ohm·m. An analysis of the MTS by area showed that objects of low resistance (LRO) are located in two conductive bands, the upper edge of which varies from 0.3 to 5 km. The bands are parallel to the DAE axis and can be considered as some part of the anomaly. A very large value of G leads to the assumption that the anomalous body extends to a considerable depth. When compared with the data of other geophysical methods, it turned out that the DAE spatially coincides with an intense (up to 90 mW/m2) linear anomaly of the deep heat flow. This fact suggests that the nature of the DAE lower part can be a partial melting of fluid-enriched heated local rocks or intrusion of mantle magma. The obtained geoelectric results support the idea of the modern tectonic activation in Donbas.
顿巴斯地电结构
顿巴斯是东欧克拉通晚泥盆纪裂谷作用的结果。在石炭纪,盆地的沉降和沉积达到了最大值,顿巴斯形成了15公里长的石炭纪沉积层。矿床总厚度达20多公里。下一个重要事件是褶皱,发生在三叠纪晚期——侏罗纪早期和白垩纪晚期——第三纪早期。倒转抬升了褶皱顿巴斯的上部,随后的侵蚀暴露了地表的石炭系含煤地层。采用磁变分剖面法(MVP)和大地电磁测深法(MTS)对深部电导率进行了研究。1986年进行了第一次大型调查(13个长期MTS站点和32个MTS点);1988年又进行了30次MTS。2012-2013年,利用现代仪器对15个MVP-MTS站点进行了简介,从而获得了更准确的结果。数据解释得出以下结论。强烈的顿巴斯电导率异常(DAE)沿褶皱顿巴斯的主背斜分布。在西北部,它在DDD中继续,在东南部,在卡平斯基涌浪上。MVP法获得的DAE参数:根据异常场的频率响应,估计出总纵向电导G=(8±2)×108S×m。地磁变化异常场的剖面图估计了异常电流中心hmax.c.curr的最大可能深度,这取决于变化周期。对于DAE,在最大频率响应Т0≈3600 s时,它等于hmax.c.curr=18±2 km。异常的上边缘是根据MTS数据估计的。大多数可用的70 MTSρκ曲线从大约相同的15欧姆·m±半个数量级的水平开始,周期为0.1-1 s。这意味着在顿巴斯,上半公里层的岩石通常具有5-50欧姆的电阻率。更深的地方,电阻率可以增加到成百上千欧姆米,或者减少到欧姆米的单位或分数。对MTS的面积分析表明,低电阻物体位于两个导电带中,其上边缘从0.3到5公里不等。这些条带平行于DAE轴,可以认为是异常的一部分。非常大的G值导致异常体延伸到相当大的深度的假设。与其他地球物理方法的数据相比,DAE在空间上与深部热流的强烈(高达90mW/m2)线性异常一致。这一事实表明,DAE下部的性质可能是富含流体的加热局部岩石的部分熔融或地幔岩浆的侵入。所获得的地电结果支持了顿巴斯现代构造活动的观点。
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来源期刊
Geofizicheskiy Zhurnal-Geophysical Journal
Geofizicheskiy Zhurnal-Geophysical Journal GEOCHEMISTRY & GEOPHYSICS-
自引率
60.00%
发文量
50
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