Feasibility study of the Conway Granite as a geothermal energy resource

The eastern part of the White Mountain batholith is dominated by four intrusive complexes, which contain similar sequences of intrusive rocks. Although the details of the sequence of intrusion differ from complex to complex, the Osceola Granite is generally an early phase, followed by the developmen...

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Bibliographic Details
Main Authors: Osberg, P. H., Wetterauer, R., Rivers, M., Bothner, W. A., Creasy, J. W.
Format: Report
Language:English
Published: Maine Univ., Orono (USA). Dept. of Geological Sciences 1978
Subjects:
Granites
Quartz
Geology
Geophysical Surveys
Geothermal Legacy
Mathematical Models
Oxides
15 Geothermal Energy
Usa Geothermal Legacy
Chalcogenides
Rocks
North Atlantic Region
Two-Dimensional Calculations
Silicon Oxides
Silicon Compounds
New Hampshire
Igneous Rocks
Oxygen Compounds
Geothermal Resources
Gravity Surveys
North America
Three-Dimensional Calculations
Resources
Conway
North Atlantic
Online Access:https://doi.org/10.2172/5780116
https://digital.library.unt.edu/ark:/67531/metadc1098764/
Description
Summary:The eastern part of the White Mountain batholith is dominated by four intrusive complexes, which contain similar sequences of intrusive rocks. Although the details of the sequence of intrusion differ from complex to complex, the Osceola Granite is generally an early phase, followed by the development of ring dikes of Albany Porphyritic Quartz Syenite and finally the intrusion of Conway Granite. One intrusive complex contains riebeckite granite as a late phase, and at least two complexes fed volcanic eruptions, some of the products of which are preserved in subsided blocks. A specialized study of the orientation of joints was made in the eastern halo of the batholith. Measurement of gravity over the eastern part of the batholith and reduction of these data allows gravity residuals to be calculated and two- and three-dimensional models for the eastern part of the batholith to be constructed. The gravity models are consistent with steeply dipping contacts with the country rocks, and the maximum depth of the eastern part of the batholith is between 4 km and 5.25 km. The temperature distribution within the eastern part of the batholith can be determined using existing parameters for heat flow, heat production, and conductivity augmented by new data for heat production. The geologic boundaries and the gravity model provide the geometric constraints for the temperature distribution. Both one- and two-dimensional models are developed. The temperature distribution varies both vertically and laterally within the batholith. Estimates of temperature beneath the batholith are 170/sup 0/C at 6 km and 220/sup 0/C at 8 km.

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