| Abstract |
Temperature, pressure, and spinner (TPS) logs have been recorded in several wells from the Dixie Valley Geothermal Reservoir in west central Nevada. A variety of well-test analyses has been performed with�these data to quantify the hydrologic properties of this fault-dominated geothermal resource. Four complementary analytical techniques were employed, their individual application depending upon availability and quality of data and validity of scientific assumptions. In some instances,�redundancy in methodologies was used to decouple interrelated terms. The methods were (1) step drawdown, variable-discharge test; (2) recovery�analysis; (3) damped-oscillation response; and (4) injection test. To date, TPS logs from five wells have been examined and results fall into two distinct categories. Productive, economically viable wells have permeability-thickness values on the order of 105 millidarcy-meter (mD-m) and storativities of about 10-3. Low-productivity wells, sometimes�located only a few kilometers from their permeable counterparts, are artesian and display a sharp reduction in permeability-thickness to about 101 mD-m with storativities on the order of 10-4. These results�demonstrate that the hydrologic characteristics of this liquid-dominated geothermal system exhibit a significant spatial variability along the range-�bounding normal fault that forms the predominant aquifer. A large-scale, coherent model of the Dixie Valley Geothermal Reservoir will require an�understanding of the nature of this heterogeneity and the parameters that control it. |