1. Geothermal Geophysics Overview �and Resistivity Techniques�
2. Geothermal Exploration Geophysics Questions
When geophysics is integrated with complete data
set in a consistent geothermal conceptual model:
What drilling target is lowest risk?
What is the capacity of the reservoir in MW?
Where should wells be targeted to prove that resource capacity?
What is the likelihood of success for the next well(s) based on analogous downside, upside and most likely conceptual models?
What range of resource capacity is consistent with the geoscience data set based on analogous downside, upside and most likely conceptual models?
3. Geothermal Geophysics Overview
What surface methods are used?
What do they measure?
How do they contribute to the conceptual model of the resource?
Why are resistivity methods relatively popular?
Why is MT a popular resistivity method?
What are some of its pitfalls?
What are the advantages of conceptual targeting, as opposed to anomaly targeting?
4. Geothermal Geophysics Methods
Mainly adapted from the petroleum and mining industries.
BUT
Mining has shallower, smaller targets.
Petroleum has different imaging needs in a different geological setting, making reflection seismic the preferred technique.
Petroleum and minerals have more value per explored volume than hot water.
5. Surface Geophysical Techniques�in Geothermal Exploration
6. Geophysical Acronyms
7. Surface Geophysical Techniques in Geothermal Exploration
8. Geophysical Exploration of Geothermal Systems
9. Geothermal Resource Characteristics Affecting Geophysics For >200C Issue
Reservoir top usually 300 to 1000 m deep Deeper
Reservoir thickness 300 to 3000 m Thicker
Testable wells usually >$1.5 million Wells cost more
Commercial wells usually >$3 million
For <200C tabular Issue
Reservoir top usually 100 to 800 m deep Shallower (for now)
Reservoir thickness 100 to 1000 m Thinner
Testable wells sometimes <$1 million Wells cost less
Commercial wells usually $1.2 to $3 million
10. Geophysical Exploration of Geothermal Systems
11. Geothermal Resource Characteristics Affecting Geophysics 2 For <200C upflow Issue
Reservoir top usually 300 to 1000 m deep similar to >200C
Reservoir thickness ? maybe >1000 m Fault zone
Testable wells usually >$1.5 million Wells cost more
Commercial wells usually $1.5 to >$3 million
For HDR/EGS Issue
Reservoir top created Dynamic
Reservoir thickness created Dynamic
Testable wells cost more Wells cost more
Commercial well cost a research issue
12. Geophysical Exploration of >200C Geothermal Systems
Resource image area > 1 km2, often > 4 km2
Exploration image area > 4 km2, often > 50 km2
Depth to reservoir top 300 to 2000 m
Access often rugged
Environmental issues
13. Conceptual Objectives for Exploration Geophysics Where is the reservoir? How big is it?
Isotherm geometry, the overall permeability constraint for reservoir simulation, can be constrained using low resistivity, temperature sensitive clay alteration
for >500 m depth: MT. Possibly VES, DC-T, CSMT etc.
for <500 depth: TEM, CSMT, AMT, VES, DC-T etc
What can extend surface geology deeper?
Gravity: lithology, dense alteration, basin geometry
Magnetics: near-surface sulfate alteration, volcanics
Where are specific well entries?
Rare validated success cases, few partial technical successes and numerous under-reported failures
Reflection seismic in geothermal often poor quality. Can characterize structure. However, entries rarely imaged.
Geochemistry and geology used with resistivity to map leaky clay cap alteration intensity and geometry (i.e. detect sweet spots not entries)
14. Surface Geothermal Geophysics�Other Than Resistivity
15. Geophysical Exploration of <200C Geothermal Systems
Resource image area > 1 km2, often > 4 km2
Exploration image area > 4 km2, often > 20 km2
Depth to reservoir top 100 to 1000 m
More like exploration for aquifers than for minerals or petroleum.
16. Conceptual Objectives for Exploration Geophysics Where is the reservoir? How big is it?
Isotherm geometry, the overall permeability constraint for reservoir simulation, can be constrained using low resistivity, temperature sensitive clay alteration
for >500 m depth: MT. Possibly VES, DC-T, CSMT etc.
for <500 depth: TEM, CSMT, AMT, VES, DC-T etc
What can extend surface geology deeper?
Gravity: lithology, dense alteration, basin geometry
Magnetics: near-surface sulfate alteration, volcanics
Where are specific well entries?
Rare validated success cases, few partial technical successes and numerous under-reported failures
Reflection seismic in geothermal often poor quality. Can characterize structure. However, entries rarely imaged.
Geochemistry and geology used with resistivity to map leaky clay cap alteration intensity and geometry.
17. Surface Geophysics Methods�for Resistivity
18. Geothermal Resistivity Pattern
19. Resistivity Acquisition Issues Noise
Pipes, fences, power lines and similar metal features usually require a standoff, typically 100 to 1000 m depending on method
Near power plants, passive methods like MT are doubtful and all methods suffer from higher noise
DC power lines can limit MT depth of investigation to <1000 m at 30 km distance and <5000 m at 100 km distance
Statics
Static distortion affects all methods that use electrodes (all but TEM)
Difficult to avoid in volcanics or rugged areas
Static correction by inversion smoothing is sometimes unrealistic
Access
Cost rises steeply if access to sites is poor
Faster methods like T-MT reduce cost only where access is easy
Cable oriented methods require wide and continuous access so more suited to Nevada than New Zealand ..
20. MT Method
21. MT Physics
22. MT Physics
23. MT Method
24. T-MT Method
25. TDEM / TEM
26. TDEM / TEM
27. Standard Geophysical Plan >200C Geothermal Exploration MT to map base of clay cap
Gas and fluid geochemistry for conceptual target
Maybe TEM for MT statics and detail
Maybe gravity for lithology and large structure
28. Resistivity Objectives �in Geothermal Exploration Map structure and conductance of <180C low resistivity smectite clay zone capping the relatively resistive reservoir
Integrate with geochemistry and geology to
Estimate resource capacity
Target wells for high temperature permeability
Estimate risk probabilities ..
29. Geothermal Resistivity Pattern
30. Salak Geothermal Field�MT Cross-section��MT Resistivity with MeB Smectite & Isotherms from Wells
32. Standard Geophysical Plan <200C Geothermal Exploration
Lowest cost resistivity to reach base of clay cap, maybe AMT, CSMT, DC, etc.
Temperature Gradient Holes if access and drilling are low cost.
Ground magnetics and gravity for geology and alteration mapping.
SP if target simple, shallow and low relief
Reflection seismic if structure is simple and manifestations are weak
33. Geothermal MT Interpretation Pitfalls
34. Exploration and Evaluation Stages and Styles
35. What To Target?�Anomaly or Conceptual Model
36. Uncertainty in Geothermal Resistivity Interpretation Noise and 3D Distortion
Anomalous parts of images should be checked for underlying data quality issues
Acquisition and interpretation should be done by different entities
Conceptual Interpretation
Resistivity methods can image the intensity of hydrothermal clay alteration and the geometry of the base of the low resistivity clay cap conforming to the geothermal reservoir
However, the apex of the clay cap may be over the shallowest permeability but not over the deep high-temperature upflow which must be inferred from less reliable alteration intensity.
so
Check conceptual advantages of other methods
Integrate with geochemistry and geology
Drill a conceptual model, NOT an anomaly
Validate geophysical interpretation after drilling ..
37. Glass Mountain Geothermal Field�MT 1D-2D-3D Resistivity and Well 17A-6��
38. Audit Geophysics with Well Data
39. Cost for Geophysics
40. Geothermal Geophysics Overview �and Resistivity Techniques�
41. VES and Dipole-dipole Resistivity at Cerro Prieto
42. VES Resistivity
43. VES and Dipole-dipole Resistivity at Cerro Prieto
44. CSMT Profiling
45. SP
46. SP
47. Microearthquakes (MEQ)�in Geothermal Exploration
48. Magnetic Surveys
49. Reflection Seismic in �Geothermal Exploration Dominates petroleum exploration
$ billions in petroleum seismic research are making incremental progress on the issues that inhibit applications to geothermal exploration:
P attenuation by shallow gas like CO2 in clay alteration
Shallow dense rocks like lavas
Statics due to rugged topography with rapid seismic velocity changes (like lavas and tuffs)
Poor velocity constraints near target depths
Scattering from closely spaced deep faults
Lack of rock contacts that coherently reflect
S-conversion interference
In these situations, petroleum exploration companies use MT, EM, gravity etc
50. Reflection Seismic �Geothermal Applications When goal is to image permeability;
not all fault segments are permeable so ideally want stress setting, not just one segment
volume velocity imaged by bending ray tomography will usually be too low resolution to resolve discrete faults at reservoir depth unless geometry and velocity are ideal.
Faults are imaged by reflection seismic in geothermal prospects with; 1) layered geology, 2) low gas flux, 3) limited shallow lava, and 4) discrete structures
Case histories image some reservoir faults but very few validated entries.
Field-margin injection wells are easier targets
If CO2 is trapped in clay cap, then perimeter of shallow reservoir permeability often matches bad data zone for reflection seismic
Clay cap sometimes imaged by p-wave bending ray velocity analyses but poorer resolution and higher cost than MT resistivity
S-wave splitting is still speculative
Therefore, still a research topic for geothermal exploration
Reflection seismic is more cost-effective when acquisition cost is lower without compromising acquisition .
51. Value of Geophysics Use decision trees to assess impact of new information
Choose three likely outcomes of the resource decision
Your best guess: what you think it is.
Typical downside: considering similar situations that were disappointing.
Likely upside: best similar case or maybe better with justification.
Assess probability of each case based mostly on 100 prospects, with Monte Carlo ranges providing context for exceptional cases. How many prospects with diagnostic information like this had an outcome better than this case?
Assess likely affect of new information on probability for each case, considering consistency and breadth of experience using similar information elsewhere.
Use decision tables to assess new information:
How much would the new information likely affect resource decision probabilities?
How much does sufficiently reliable information cost?
What other information would affect the same resource probabilities and is it more cost-effective?
52. Geophysical Confidence Levels
