1979
DOI: 10.1016/0040-1951(79)90297-x
|View full text |Cite
|
Sign up to set email alerts
|

Geothermal characteristics of the colorado plateau

Help me understand this report

Search citation statements

Order By: Relevance

Paper Sections

Select...
2
1
1
1

Citation Types

1
14
0

Year Published

1983
1983
2020
2020

Publication Types

Select...
6
2
1

Relationship

0
9

Authors

Journals

citations
Cited by 41 publications
(15 citation statements)
references
References 11 publications
1
14
0
Order By: Relevance
“…Deposition of 4 km of overlying sediment would be required to place the sampled limestone horizon at a temperature of , 120uC (the warmest sample temperature estimated by clumped-isotope thermometry), assuming a mean annual surface temperature of 20uC through most of the pre-Miocene (Fricke and Wing 2008;Yapp 2008) and a geothermal gradient of 25uC/km. If a higher geothermal gradient characteristic of volcanic source areas on the plateau is considered (40uC/km, Reiter et al 1979), 2.5 km of sediment would be required. At the sample locality on the Coconino Plateau, the precise maximum depth of burial of the samples is unknown, because no record remains of mid-Eocene through early Miocene sediment that may have accumulated and then been eroded above the Music Mountain Formation prior to emplacement of the late Miocene basalt.…”
Section: Thermal History Of Long Point Samplesmentioning
confidence: 99%
“…Deposition of 4 km of overlying sediment would be required to place the sampled limestone horizon at a temperature of , 120uC (the warmest sample temperature estimated by clumped-isotope thermometry), assuming a mean annual surface temperature of 20uC through most of the pre-Miocene (Fricke and Wing 2008;Yapp 2008) and a geothermal gradient of 25uC/km. If a higher geothermal gradient characteristic of volcanic source areas on the plateau is considered (40uC/km, Reiter et al 1979), 2.5 km of sediment would be required. At the sample locality on the Coconino Plateau, the precise maximum depth of burial of the samples is unknown, because no record remains of mid-Eocene through early Miocene sediment that may have accumulated and then been eroded above the Music Mountain Formation prior to emplacement of the late Miocene basalt.…”
Section: Thermal History Of Long Point Samplesmentioning
confidence: 99%
“…Processes producing uplift are often associated with thermal phenomena generating an increase in terrestrial heat fl ow. Over the past several decades, lithosphere warming, Moho underplating, and continental delamination have all been suggested as mechanisms of uplift for the Colorado Plateau (Crough and Thompson, 1976;Reiter et al, 1979;Bird, 1979;Bodell and Chapman, 1982;Morgan and Swanberg, 1985;Roy et al, 2009). As such, there are a number of phenomena possibly contributing to Colorado Plateau uplift; the question is which phenomena contributed most signifi cantly (Flowers, 2010).…”
Section: Introductionmentioning
confidence: 99%
“…The heat-fl ow temperature measurements (temperature logs) in the area are distinctly deep enough that it is thought that shallower perturbations such as groundwater movement are minimized. The aerial data set provides a mean with little noise, and although the data are several decades old (Reiter et al, 1979;Reiter and Mansure, 1983), they are unique and most suitable for the present study.…”
Section: Introductionmentioning
confidence: 99%
“…This is close to the values of 55-65 mW m-' reported by Bodell & Chapman (1982) for the Colorado Plateau immediately south of the Uinta Basin and the values of 63mWm-' (Sass et af. 1971) and 65mWm-* (Reiter et al 1979) determined in the Uinta Basin. These observations suggest heat flow is consistently 55-65 mW m-' in the northern Colorado Plateau and Uinta Basin and is not the cause of the observed temperature variations.…”
Section: Interpretation Of the Spatial Variationmentioning
confidence: 99%