The role of crustal extension in the metamorphism of Proterozoic rocks in northern New Mexico

Grambling, Jeffrey A.; Williams, Michael L.; Smith, Roger F.; Mawer, Christopher K.

doi:10.1130/spe235-p87

Cited by 31 publications

(28 citation statements)

References 8 publications

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“…The limited available data seem to reflect a predominance of amphibolite-grade conditions, typical of much of Colorado and New Mexico (e.g., 'Ihreto, 1987;Grambling, 1988;Reed et al, 1993), although anomalous granulite-grade rocks occur in the Wet Mountains ( Fig. 2; Brock and Singewald, 1968;Ttveto, 1987) and northern Thos Range (Grambling et al, 1989;Pedrick, 1995;Pedrick et al, 1998).…”

Section: Metamorphismmentioning

confidence: 95%

The Yavapai-Mazatzal crustal boundary in the Southern Rocky Mountains

Shaw

Karlstrom

1999

Rocky Mountain Geology

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A major geologic boundary has been proposed in the Southern Rocky Mountains separating Proterozoic crustal provinces with different ages and tectonic histories. These provinces probably correlate with the Yavapai (1.8-1.7 Ga) and Mazatzal (1.7-1.6 Ga) provinces of Arizona. Geologic, geochemical, geochronologic, and xenolith data suggest that the boundary lies within a ~3 0 0 km-wide zone that trends northeastward through southern Colorado and northern New Mexico. This zone also seems to have focused later tectonic and thermal effects. However, no major shear zone that might represent a discrete tectonic suture has been identified in the area, and there is no agreement on precisely where the boundary is or what tectonic significance it may have.We present a review of evidence supporting extrapolation of the Yavapai-Mazatzal boundary through the Southern Rocky Mountains. Limitations in the precision, quantity, and interpretation of available data probably contribute to disagreement over the location of the boundary. However, the disparity in boundaries defined by different data sets may partly reflect a complex or gradational transition between crustal domains. We propose a speculative model for the boundary based on a preliminary structural analysis. lkctonic fabrics appear to be consistent with the initial juxtaposition of arc terranes of the Yavapai and Mazatzal provinces on a lowangle thrust system with later modification and steepening of the boundary during continued crustal shortening. This model explains the diffuse isotopic boundary as a manifestation of a vertically heterogeneous crustal column that might promote isotopic mixing. The cryptic structural expression of the suture may result from a layer-parallel style of suturing and complex post-accretionary tectonic overprinting.

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Section: Metamorphismmentioning

confidence: 95%

The Yavapai-Mazatzal crustal boundary in the Southern Rocky Mountains

Shaw

Karlstrom

1999

Rocky Mountain Geology

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“…the southwestern United States (Grambling 1986;Grambling et al 1989;Grambling & Dallmeyer 1993); the Arunta Inlier in central Australia (Collins & Vernon 1991, 1993Hand et al 1992Hand et al , 1993Vernon 1996)), although sometimes with good reason, such as paths that are clockwise in the hanging wall and anticlockwise in the footwall of an overthrust complex (e.g. southern Alaska (Sisson & Hollister 1988)).…”

Section: P-t Paths In Low P/t Ratio Metamorphic Beltsmentioning

confidence: 98%

Ridge-trench interactions and high- T -low- P metamorphism, with particular reference to the Cretaceous evolution of the Japanese Islands

Brown

1998

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A corollary of plate tectonics is that spreading ridges ultimately interact with trenches; this is a consequence of the closure phase of the Wilson cycle that eliminates ocean basins. Ridge-trench interactions generate distinctive igneous, metamorphic, structural and sedimentation effects, which commonly are diachronous parallel to the trench; effects vary with plate boundary geometry and rate of migration is controlled by relative motion vectors. Identification of such interactions in the geological record is uncommon, which suggests that geological events triggered by ridge trench interactions are attributed to other phenomena, such as changes in plate motion or a singularity at the trench. The estimated greater length of plate boundaries in the past means that subduction of a spreading ridge system could have been more common earlier in Earth history.High-T-low-P metamorphism requires a tectonic setting that allows enhanced heat flux, transient advection of heat due to magma ascent, unusually large internally generated heat, or some combination of these features. Subduction of a spreading ridge system produces anomalously high temperatures at shallow crustal depth through the development of a slab window, which allows transfer of sub-slab asthenospheric mantle across the slab to create an enhanced heat flux beneath the overriding plate. This process is important along convergent margins that develop a subduction-accretion complex, and drives low P/T ratio metamorphism and anatexis of the complex. Heat transport occurs by rising magma near the trench, which leads to formation of plutons with characteristic contaminated MORB geochemistry. Near-trench igneous activity and low PIT ratio metamorphism are the most striking features attributable to spreading ridge subduction and slab window formation, and together are likely to be diagnostic of ridge trench interactions.

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“…The Proterozoic history of the New Mexico region is very complex and is the subject of much current research and debate (e.g., Bauer and Williams, 1985;Condie and Budding, 1979;Condie, 1986;Grambling et al, 1988Grambling et al, ,1989Williams, 1990). There are a number of complex dipping reflectors in the basement.…”

Section: Milesmentioning

confidence: 99%

“…The best-documented early event was thrusting of Precambrian rocks coupled with metamorphism (Grambling et al, 1988(Grambling et al, , 1989. The seismic data show that many reflectors are present in the basement.…”

Section: Introductionmentioning

confidence: 96%

“…These authors suggested that at least some of the terrane boundaries were north-verging ductile thrusts. However, Grambling et al (1989) demonstrated that extension also played a major role in the Proterozoic evolution of the region north of the Estancia Basin. Geochronologic studies (Dallmeyer et al, 1990) indicate that the extension occurred at about 1,440 Ma and that the thrusting occurred at about 1,350 Ma.…”

Section: Introductionmentioning

confidence: 97%

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An integrated geophysical study of the Estancia Basin, central New Mexico

Barrow

Keller

1994

Basins of the Rio Grande Rift: Structure, Stratigraphy, and Tectonic Setting

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This study focuses on the interpretation of seismic reflection lines, gravity, and well data in the EstanciaBasin, which is located along the eastern margin of the Rio Grande rift in central New Mexico. Major new data introduced are seven seismic reflection lines provided by the Mobil Exploration and Production Company. The basin began to form during Late Mississippian and Early Pennsylvanian uplift of the Ancestral Rocky Mountains. Laramide-age thrusting and folding occurred west of the basin and may have caused strike-slip movements in the basin. Limited packages of Tertiary rocks occur in local outcrops, and small normal faults associated with the Rio Grande rift are the latest structural features in the basin. An integrated interpretation of the seismic reflection data and other geophysical and geological data make the following observations and interpretations possible: (1) the Pennsylvanian basin is a narrow, fault-bounded trough with a north-south trend;(2) the eastern boundary of this trough is a strike-slip fault that was probably active during formation of the basin; (3) this strike-slip fault was also probably active in the Laramide and possibly active in the Precambrian; (4) there are many prominent dipping reflectors in the Precambrian basement that may represent ductile shear zones, and (5) the effects of the Rio Grande rifting in the area were minor.

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The role of crustal extension in the metamorphism of Proterozoic rocks in northern New Mexico

Cited by 31 publications

References 8 publications

The Yavapai-Mazatzal crustal boundary in the Southern Rocky Mountains

The Yavapai-Mazatzal crustal boundary in the Southern Rocky Mountains

Ridge-trench interactions and high- T -low- P metamorphism, with particular reference to the Cretaceous evolution of the Japanese Islands

An integrated geophysical study of the Estancia Basin, central New Mexico

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