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

Ponce, David A.; Glen, Jonathan M.G.

doi:10.1130/ges00117.1

Cited by 8 publications

(8 citation statements)

References 49 publications

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“…Previous workers have suggested that the location and trend of the NNR may have been controlled by an existing crustal structure (e.g., Theodore et al, 1998;John et al, 2000;Ponce and Glen, 2008). This structure has been interpreted as a near-vertical crustal-scale fault parallel and adjacent to the NNR based on resistivity (Grauch et al, 2003) and gravity data (Ponce and Glen, 2008).…”

Section: Orientation Of the Northern Nevada Riftmentioning

confidence: 96%

“…This structure has been interpreted as a near-vertical crustal-scale fault parallel and adjacent to the NNR based on resistivity (Grauch et al, 2003) and gravity data (Ponce and Glen, 2008). In the right circumstances, dikes can propagate along fractures that are not perpendicular to the least principal stress (e.g., Delaney et al, 1986), but NNR dikes do not appear to intrude preexisting faults where exposed in the fi eld and it is diffi cult to argue they record anything other than the least principal stress in the central part of the area shown in Figure 2 from ca.…”

Section: Orientation Of the Northern Nevada Riftmentioning

confidence: 99%

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Reappraisal of the relationship between the northern Nevada rift and Miocene extension in the northern Basin and Range Province

Colgan

2013

Geology

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The northern Nevada rift is a prominent mafi c dike swarm and magnetic anomaly in north-central Nevada inferred to record the Middle Miocene (16.5-15.0 Ma) extension direction in the northern Basin and Range province in the western United States. From the 245°-250° rift direction, Basin and Range extension is inferred to have shifted 45° clockwise to a modern direction of 290°-300° during the late Miocene. The region surrounding the northern Nevada rift was actively extending while the rift formed, and these domains are all characterized by extension oriented 280°-300°. This direction is distinctly different from the rift direction and nearly identical to the modern Basin and Range direction. Although the rate, structural style, and distribution of Basin and Range extension appear to have undergone a signifi cant change in the late Miocene (ca. 10 Ma), the overall spreading direction does not. Middle Miocene extension was directed perpendicular to the axis of the thickest crust formed during Mesozoic shortening and this orientation may refl ect gravitational collapse of this thick crust. Orientation of northern Nevada rift dikes may refl ect a short-lived regional stress fi eld related to the onset of Yellowstone hotspot volcanism.

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Section: Orientation Of the Northern Nevada Riftmentioning

confidence: 96%

Section: Orientation Of the Northern Nevada Riftmentioning

confidence: 99%

Reappraisal of the relationship between the northern Nevada rift and Miocene extension in the northern Basin and Range Province

Colgan

2013

Geology

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“…There is a pronounced gravity gradient, increasing from west to east, at the western edge of the rift. This steep gradient is visible on all profi les to the south, except profi le EE', and likely refl ects the juxtaposition of dense basement rocks east of the eastern north-ern Nevada rift, with less dense basin deposits and basement rocks west of the rift (Ponce and Glen, 2008). In profi le EE', the gravity gradient is less pronounced because the eastern northern Nevada rift is juxtaposed against dense Paleozoic rocks on the west in the Shoshone Range, which decreases the density contrast.…”

Section: Profi Le Aa'mentioning

confidence: 96%

“…Glen and Ponce (2002) describe several large-scale, NNW-trending, arcuate, mid-Miocene crustal structures in northern Nevada, including the eastern northern Nevada rift, which passes just west of the Beowawe geothermal system and is the focus of this study. The eastern northern Nevada rift has been divided into multiple segments from north to south based on interpretationof magnetic data (Zoback et al, 1994;Ponce and Glen, 2008). Zoback and Thompson (1978) and Glen and Ponce (2002) speculate the eastern northern Nevada rift and other associated rifts were localized along regional crustal fractures that were reactivated during emergence of the Yellowstone hotspot along the Oregon-Idaho border.…”

Section: Regional and Local Geology And Resourcesmentioning

confidence: 99%

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Three-dimensional geologic model of the northern Nevada rift and the Beowawe geothermal system, north-central Nevada

Watt¹,

Glen²,

John³

et al. 2007

Geosphere

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A three-dimensional (3D) geologic model of part of the northern Nevada rift encompassing the Beowawe geothermal system was developed from a series of two-dimensional (2D) geologic and geophysical models. The 3D model was constrained by local geophysical, geologic, and drill-hole information and integrates geologic and tectonic interpretations for the region. It places important geologic constraints on the extent and confi guration of the active Beowawe geothermal system. The geologic framework represented in this model facilitates hydrologic modeling of the Beowawe geothermal system and evaluation of fl uid fl ow in faults and adjacent rock units.Basin depths were determined using an iterative gravity-inversion technique that calculates the thickness of low-density, basin-fi lling deposits. The remaining subsurface structure was modeled using 2D potential-fi eld modeling software. Crustal cross sections from the 2D models were generalized for use in the 3D model and consist of six stratigraphic layers defi ned as low-density basin sediments, volcanic rocks, basalt-andesite rocks of the northern Nevada rift, Jurassic and Cretaceous intrusive rocks, and Paleozoic siliceous and carbonate sedimentary rocks of the upper and lower plates of the Roberts Mountains allochthon, respectively. This simplifi ed stratigraphy was combined with mapped surface geology and was extrapolated across the 3D model area. Features along the northern Nevada rift depicted by the model may represent preexisting crustal structures that controlled the locations and character of Ter-tiary tectonic and magmatic events related to Basin and Range extension and emplacement of the middle Miocene northern Nevada rift. Several of the geologic features represented are important components of the Beowawe geothermal system. Prominent ENE-trending faults (e.g., Malpais fault) that bound the southern edge of Whirlwind Valley, and older NNW-striking faults (e.g., Dunphy Pass and Muleshoe faults) that form major features of the model, are likely important pathways for geothermal fl uids and groundwater fl ow from the Humboldt River, which may recharge the Beowawe system.

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Uplift, rupture, and rollback of the Farallon slab reflected in volcanic perturbations along the Yellowstone adakite hot spot track

et al. 2017

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Field, geochemical, and geochronological data show that the southern segment of the ancestral Cascades arc advanced into the Oregon back‐arc region from 30 to 20 Ma. We attribute this event to thermal uplift of the Farallon slab by the Yellowstone mantle plume, with heat diffusion, decompression, and the release of volatiles promoting high‐K calc‐alkaline volcanism throughout the back‐arc region. The greatest degree of heating is expressed at the surface by a broad ENE‐trending zone of adakites and related rocks generated by melting of oceanic crust from the Farallon slab. A hiatus in eruptive activity began at ca. 22–20 Ma but ended abruptly at 16.7 Ma with renewed volcanism from slab rupture occurring in two separate regions. The eastern rupture resulted in the extrusion of Steens Basalt during the ascent and melting of a dry mantle (plume) source contaminated with depleted mantle. The contemporaneous western rupture resulted in renewed subduction, melting of a wet mantle source, and the rejuvenation of high‐K calc‐alkaline volcanism near the Nevada‐California border at 16.7 Ma. Here the initiation of slab rollback is evident in the westward migration of arc volcanism at 7.8 km/Ma. Today, the uplifted slab is largely missing beneath the Oregon back‐arc region, replaced instead by a seismic hole that is bound on the south by the adakite hot spot track. We attribute slab destruction to thermal uplift and mechanical dislocation that culminated in rapid tearing of the slab from 17–15 Ma and possible foundering and sinking of slab segments from 16 to 10 Ma.

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

Cited by 8 publications

References 49 publications

Reappraisal of the relationship between the northern Nevada rift and Miocene extension in the northern Basin and Range Province

Reappraisal of the relationship between the northern Nevada rift and Miocene extension in the northern Basin and Range Province

Three-dimensional geologic model of the northern Nevada rift and the Beowawe geothermal system, north-central Nevada

Uplift, rupture, and rollback of the Farallon slab reflected in volcanic perturbations along the Yellowstone adakite hot spot track

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