A shallow rift basin segmented in space and time: The southern San Luis Basin, Rio Grande rift, northern New Mexico, U.S.A.

Q3 Earth and Planetary Sciences

Rocky Mountain Geology Pub Date : 2019-12-01 DOI:10.24872/RMGJOURNAL.54.2.97

B. Drenth, V. Grauch, K. Turner, B. Rodriguez, Ren A. Thompson, P. Bauer

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引用次数: 8

Abstract

Interpretation of gravity, magnetotelluric, and aeromagnetic data in conjunction with geologic constraints reveals details of basin geometry, thickness, and spatiotemporal evolution of the southern San Luis Basin, one of the major basins of the northern Rio Grande rift. Spatial variations of low-density basin-fill thickness are estimated primarily using a 3D gravity inversion method that improves on previous modeling efforts by separating the effects of the low-density basin fill from the effects of pre-rift rocks. The basin is found to be significantly narrower—and more complex in the subsurface—than indicated or implied by previous modeling efforts. The basin is also estimated to be significantly shallower than previously estimated. Five distinct subbasins are recognized within the broader southern San Luis Basin. The oldest and shallowest subbasin is the Las Mesitas graben along the northwestern basin margin, formed during the Oligocene transition from Southern Rocky Mountain volcanic field magmatism to rifting. In this subbasin, sediments are estimated to reach a maximum thickness of ~400 m within a north–south elongated structural depression. Other subbasins that likely initially developed during the Miocene are the dominant tectonic features in the southern San Luis Basin. This includes the Tres Orejas subbasin, which formed in the southwestern portion of the basin by the Embudo fault zone and a hypothesized fault zone along its western margin. This subbasin reaches a maximum thickness of ~2 km, as indicated by magnetotelluric and gravity modeling. The Sunshine Valley, Questa, and Taos subbasins occupy the eastern part of the southern San Luis Basin. The southern Sangre de Cristo fault zone is the dominant tectonic feature that controlled their development after ~20 Ma. The east-down Gorge fault zone controlled the western margins of significant parts of these eastern subbasins, although much of the Taos subbasin may be superimposed on the Tres Orejas subbasin. Maximum low-density basin-fill thicknesses are estimated to be 1.2 km for the Sunshine Valley subbasin, 800 m for the Questa subbasin, and 1.8 km for the Taos subbasin. Subbasin-forming tectonic activity along the Gorge fault zone and within the Tres Orejas subbasin ceased by the end of the development of the largely Pliocene Taos Plateau volcanic field. After that, rift-related subsidence became more narrowly centered on the eastern margin of the basin, controlled mainly by the linked Embudo and southern Sangre de Cristo fault zones.

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在空间和时间上分割的浅裂谷盆地:美国新墨西哥州北部的圣路易斯盆地南部，里约热内卢大裂谷

结合地质条件对重力、大地电磁和航磁资料的解释，揭示了北里约热内卢大裂谷主要盆地之一的圣路易斯盆地南部的盆地几何形状、厚度和时空演化的细节。低密度盆地填充物厚度的空间变化主要使用3D重力反演方法进行估算，该方法通过将低密度盆地填充物的影响与裂谷前岩石的影响分离开来，改进了之前的建模工作。研究发现，该盆地比以前的建模工作所表明或暗示的要窄得多，在地下也更复杂。据估计，该盆地也比先前估计的浅得多。在更广阔的圣路易斯盆地南部，可以识别出五个不同的子盆地。最古老、最浅的次盆地是沿盆地西北部边缘的Las Mesitas地堑，形成于渐新世南落基火山场岩浆作用向裂谷作用过渡时期。在该次盆地中，沉积厚度最大可达~400 m，分布在南北拉长的构造凹陷内。圣路易斯盆地南部的主要构造特征是其他可能在中新世开始发育的次盆地。这包括在盆地西南部由恩布多断裂带和沿其西缘的假定断裂带形成的特雷斯奥列哈斯次盆地。根据大地电磁和重力模拟，该次盆地最大厚度约为2 km。阳光谷、奎斯塔和陶斯子盆地占据了圣路易斯盆地南部的东部。南桑格雷德·克里斯多断裂带是~ 20ma以后控制其发育的主要构造特征。东下峡谷断裂带控制了这些东部次盆地的大部分西缘，尽管陶斯次盆地的大部分可能叠加在特雷斯奥列哈斯次盆地上。据估计，阳光谷次盆地的最大低密度盆地填充厚度为1.2 km, Questa次盆地为800 m, Taos次盆地为1.8 km。沿峡谷断裂带和特雷斯-奥列哈斯次盆地的次盆地形成构造活动在大部分上新世陶斯高原火山场发育结束时停止。此后，裂谷相关的沉降变得更加狭窄，主要集中在盆地的东部边缘，主要受连接的恩布多断裂带和南部桑格里德克里斯多断裂带控制。

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来源期刊

Rocky Mountain Geology Earth and Planetary Sciences-Geology

CiteScore

1.10

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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.