| Title | Geothermal Prospecting in Utah: A New Thermal Model of the Black Rock Desert |
|---|---|
| Authors | Hardwick, Christian L.; Kirby, Stefan; Gwynn, Mark |
| Year | 2014 |
| Conference | Geothermal Resources Council Transactions |
| Keywords | Geothermal; exploration; geophysics; gravity; Pavant Butte; Sevier Desert; Black Rock Desert; Sevier Thermal Anomaly; heat flow; conduction |
| Abstract | Results from recent geophysical, hydrological, and heat flow projects to assess the geothermal potential of the Black Rock Desert (BRD) in Utah have been combined with historical data to create new 3-dimensional (3D) conductive heat transfer models using a finite-element modeling program (COMSOL Multiphysics 4.3b). The insulating effect of thick (up to 3 km), low-thermal-conductivity sediments along with typical Basin and Range heat-flow values (80 to 90 mW/m2) in deep basins results in higher temperatures compared to surrounding bedrock geotherms. Preliminary assessments revealed an area of approximately 350 km2 with temperatures above 150?C at 3 km depth and an inner 60 km2 area with temperatures above 200?C at the same depth. Temperature at depth and surface heat flow are not evenly distributed throughout the BRD. The relatively low observed surface heat flow and temperatures at depth in the southern BRD may be a consequence of local groundwater flushing over the regional background heat flow. A high-heat-flow area situated in the central BRD is thought to be associated with the more recent volcanic activity in the study area. We present new heat transfer models constrained by existing data from known geothermal gradients and material properties to explore the extent and character of geothermal potential in the BRD. New thermal models help characterize and enhance understanding of the dynamics of the BRD and other unconventional geothermal systems in the Great Basin. |