A prominent geophysical feature along the northern Nevada Rift and its geologic implications, north-central Nevada

We consider the origin and character of a prominent large-scale geophysical feature in north-central Nevada that is coincident with the western margin of the northern Nevada rift--a mid-Miocene rift that includes mafic dike swarms and associated volcanic rocks expressed by a NNW-striking magnetic an...

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Bibliographic Details
Published in:Geosphere (Boulder, Colo.) Colo.), 2008-01, Vol.4 (1), p.207-217
Main Authors: Ponce, D. A, Glen, Jonathan M. G
Format: Article
Language:English
Subjects:
airborne methods
applied (geophysical surveys & methods)
basement
Basin and Range Province
Cenozoic
Economic geology
epithermal processes
geophysical methods
geophysical surveys
Geophysics
gold ores
gravity anomalies
gravity methods
magnetic anomalies
magnetic methods
metal ores
metallogeny
mineral deposits, genesis
Miocene
Neogene
Nevada
Nevada Rift
North America
north-central Nevada
plate tectonics
rift zones
rifting
Structural geology
surveys
tectonics
Tertiary
United States
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Summary:We consider the origin and character of a prominent large-scale geophysical feature in north-central Nevada that is coincident with the western margin of the northern Nevada rift--a mid-Miocene rift that includes mafic dike swarms and associated volcanic rocks expressed by a NNW-striking magnetic anomaly. The geophysical feature also correlates with mid-Miocene epithermal gold deposits and is coincident with the central part of the Battle Mountain-Eureka mineral trend. The Reese River Valley, a 2-km-deep Cenozoic basin, is located along the western margin of this feature and is inferred from the inversion of gravity data to be influenced by, and perhaps in part structurally controlled by, the geophysical feature. Geophysical modeling indicates that the source of the geophysical anomaly must extend to mid-crustal depths, perhaps reflecting a transition from Paleozoic crust in the southwest to Precambrian crust in the northeast, the presence of felsic intrusive rocks in the middle crust, or the edge of mid- to sub-crustal mafic intrusions related to late Tertiary magmatic underplating associated with hotspot magmatism. These cases offer very different possibilities for the age, depth, and origin of the source of the geophysical anomaly, and they present distinct implications for crustal evolution in the northern Great Basin. For example, if the anomaly is due to a pre-Cenozoic basement structure, then its coincidence with the mid-Miocene northern Nevada rift suggests that the trend of the rift was guided by the pre-existing crustal structure. On the other hand, if the anomaly is related to Tertiary mafic intrusions, then the western limit of this magmatism may have been influenced by hotspot fracturing of the crust.
ISSN:1553-040X
1553-040X
DOI:10.1130/GES00117.1