1. Resistivity Practical The Crossley Heath School, Halifax
27/04/2019
Resistivity Practical
Will Brown
The Crossley Heath School, Halifax

2. Practical
27/04/2019
A construction firm is looking to build new houses in Silsden, Yorkshire.
They want to know if sites near the River Aire are suitable or not so have called a geophysical contractor to survey possible sites (us!).
There are no boreholes nearby so exact measurements are not available.
They want to know:
Where is the bedrock?
Is the bedrock level?
Where is the water table?

3. Practical We recon. the site before doing a proper survey:
27/04/2019
We recon. the site before doing a proper survey:
The site is a grassy field sloping slightly to the river, it’s spring time and the surface is dry.
We know the local geology is Millstone Grit (sandstone) the surface soil is river sediment.
Looking at the nearby river bank we can see the water is high and can see about 1m of soil before the bank cuts into rock.
We then do a desk study:
What are the resistivity properties of the area likely to be?
What would we expect to see with a resistivity survey?
Is this type of survey suitable?

4. Practical
27/04/2019

5. Practical We decide to go ahead with a resistivity survey.
27/04/2019
We decide to go ahead with a resistivity survey.
We want to see the depths of the subsurface layers and how they change horizontally – a pseudo-section.
We take 8 soundings parallel to each other, using electrode spacings from m:
Soundings
River Aire
Section - Centre line

6. Practical We decide to go ahead with a resistivity survey.
27/04/2019
We decide to go ahead with a resistivity survey.
We want to see the depths of the subsurface layers and how they change horizontally – a pseudo-section.
We take 8 soundings parallel to each other, using electrode spacings from m:
Soundings
River Aire
Section - Centre line

7. Practical We decide to go ahead with a resistivity survey.
27/04/2019
We decide to go ahead with a resistivity survey.
We want to see the depths of the subsurface layers and how they change horizontally – a pseudo-section.
We take 8 soundings parallel to each other, using electrode spacings from m:
Soundings
River Aire
Section - Centre line
20m

8. Practical We decide to go ahead with a resistivity survey.
27/04/2019
We decide to go ahead with a resistivity survey.
We want to see the depths of the subsurface layers and how they change horizontally – a pseudo-section.
We take 8 soundings parallel to each other, using electrode spacings from m:
Soundings
River Aire
Section - Centre line
20m
128m

9. Practical Profile Sounding 128m Sounding 1 20m Sounding 8
27/04/2019
Soundings ρa
spacing a (m)
log(a/h) 1 2 3 4 5 6 7 8
log(ρa/ρ1)
0.25
1838
2351
2626
1752
2367
2343
2052
1698
0.5
1738
2538
3289
2098
2134
2469
2147
1588
1231
3170
1979
974
1947
2263
1223
1074
1139
1803
1080
563
900
1115
805
772
506
507
371
272
322
432
403
399
350
252
205
190
198
211
264 16
602
408
292
210
194
168
153
126 32
1096
643
434
303
247
163
111
119 64
2812
1123
690
485
402
277
181 90
128
5851
4195
2274
921
689
411
237 85
Profile
Sounding
Sounding 1
River Aire
Section - Centre line
20m
128m
Sounding 8

10. Practical
27/04/2019
A pseudo-section is an approximation of a depth section, not actual depth.
Less than 1000Ωm
Greater than 1000Ωm
Soundings ρa
spacing a (m)
log(a/h) 1 2 3 4 5 6 7 8
log(ρa/ρ1)
0.25
1838
2351
2626
1752
2367
2343
2052
1698
0.5
1738
2538
3289
2098
2134
2469
2147
1588
1231
3170
1979
974
1947
2263
1223
1074
1139
1803
1080
563
900
1115
805
772
506
507
371
272
322
432
403
399
350
252
205
190
198
211
264 16
602
408
292
210
194
168
153
126 32
1096
643
434
303
247
163
111
119 64
2812
1123
690
485
402
277
181 90
128
5851
4195
2274
921
689
411
237 85
Dry soil Ωm
Water saturated soil Ωm
Sandstone
1000’s Ωm

11. What do these regions represent?
27/04/2019
What do these regions represent?
Less than 1000Ωm
Greater than 1000Ωm
Soundings ρa
spacing a (m)
log(a/h) 1 2 3 4 5 6 7 8
log(ρa/ρ1)
0.25
1838
2351
2626
1752
2367
2343
2052
1698
0.5
1738
2538
3289
2098
2134
2469
2147
1588
1231
3170
1979
974
1947
2263
1223
1074
1139
1803
1080
563
900
1115
805
772
506
507
371
272
322
432
403
399
350
252
205
190
198
211
264 16
602
408
292
210
194
168
153
126 32
1096
643
434
303
247
163
111
119 64
2812
1123
690
485
402
277
181 90
128
5851
4195
2274
921
689
411
237 85

12. What do these regions represent?
27/04/2019
What do these regions represent?
Less than 1000Ωm
Greater than 1000Ωm
Soundings ρa
spacing a (m)
log(a/h) 1 2 3 4 5 6 7 8
log(ρa/ρ1)
0.25
1838
2351
2626
1752
2367
2343
2052
1698
0.5
1738
2538
3289
2098
2134
2469
2147
1588
1231
3170
1979
974
1947
2263
1223
1074
1139
1803
1080
563
900
1115
805
772
506
507
371
272
322
432
403
399
350
252
205
190
198
211
264 16
602
408
292
210
194
168
153
126 32
1096
643
434
303
247
163
111
119 64
2812
1123
690
485
402
277
181 90
128
5851
4195
2274
921
689
411
237 85
Dry soil
Saturated soil
Bedrock?

13. Practical Calculate log(ρa/ρ1) and log(a/h) to plot on master curve:
27/04/2019
Calculate log(ρa/ρ1) and log(a/h) to plot on master curve:
k = (ρ2- ρ1)/( ρ1+ ρ2)
ρ1=1698Ωm
a is the electrode spacing
h is the depth of the first layer
Assume h=1
(h) Assumed to be =1 from min depth of drift on river bank. Rho1 taken from shallowest sounding in line 8. Draw a table of: (a), log(a/h), (rho a for sounding 8), log(rho a/rho1).

14. Practical k = (ρ2- ρ1)/( ρ1+ ρ2) ρ1=1698Ωm a is the electrode spacing
27/04/2019
Log(a/h)
-0.6
-0.3
0.3
0.6
0.9
1.2
1.51
1.81
2.11
Log(ρa/ ρ1)
-0.03
-0.14
-0.31
-0.62
-0.81
-1.13
-1.15
-1.28
-1.3
k = (ρ2- ρ1)/( ρ1+ ρ2)
ρ1=1698Ωm
a is the electrode spacing
h is the depth of the first layer
Assume h=1
What do you expect to happen if h ≠1m?

15. Practical We can read off k: k = -0.9 We also know that:
27/04/2019
Log(a/h)
-0.6
-0.3
0.3
0.6
0.9
1.2
1.51
1.81
2.11
Log(ρa/ ρ1)
-0.03
-0.14
-0.31
-0.62
-0.81
-1.13
-1.15
-1.28
-1.3
We can read off k:
k = -0.9
We also know that:
k = (ρ2- ρ1)/( ρ1+ ρ2)
What is the second layer resistivity?
ρ2 = ?

16. Practical k = (ρ2- ρ1)/( ρ1+ ρ2) k = -0.9 ρ1 = 1698Ωm
27/04/2019
Log(a/h)
-0.6
-0.3
0.3
0.6
0.9
1.2
1.51
1.81
2.11
Log(ρa/ ρ1)
-0.03
-0.14
-0.31
-0.62
-0.81
-1.13
-1.15
-1.28
-1.3
k = (ρ2- ρ1)/( ρ1+ ρ2)
k = -0.9
ρ1 = 1698Ωm
ρ2 = (-ρ1-k*ρ1)/(k-1)
ρ2 = 100Ωm

17. Practical Why might the curves not match?
27/04/2019
Log(a/h)
-0.6
-0.3
0.3
0.6
0.9
1.2
1.51
1.81
2.11
Log(ρa/ ρ1)
-0.03
-0.14
-0.31
-0.62
-0.81
-1.13
-1.15
-1.28
-1.3
Why might the curves not match?
What is h, the depth of the first layer?
Remember:

18. Practical h = 1m h = 2m k = (ρ2- ρ1)/( ρ1+ ρ2) k = -0.9 ρ1 = 1698Ωm
27/04/2019
Log(a/h)
-0.6
-0.3
0.3
0.6
0.9
1.2
1.51
1.81
2.11
Log(ρa/ ρ1)
-0.03
-0.14
-0.31
-0.62
-0.81
-1.13
-1.15
-1.28
-1.3
k = (ρ2- ρ1)/( ρ1+ ρ2)
k = -0.9
ρ1 = 1698Ωm
ρ2 = (-ρ1-k*ρ1)/(k-1)
ρ2 = 100Ωm
What is h, the depth of the first layer?
Remember:
h = 1m
h = 2m

19. Practical Our clients wanted to know: Where is the bedrock?
27/04/2019
Our clients wanted to know:
Where is the bedrock?
2. Is the bedrock level?
3. Where is the water table?

20. Did we succeed? (Are we getting paid!)
Practical
27/04/2019
Our clients wanted to know:
Where is the bedrock?
We saw it at the first few soundings, probably at least >64m deep.
2. Is the bedrock level?
No, it appears to dip toward the river but we can’t be certain how much or how far.
3. Where is the water table?
Within the soil layer, >2m below surface.
Did we succeed? (Are we getting paid!)

21. Geophysics for A-level Physicists
27/04/2019
Geophysics for
A-level Physicists
Will Brown

22. What is geophysics? Literally: “geo” – Earth, physics.
27/04/2019
What is geophysics?
Literally: “geo” – Earth, physics.
Study of the physics behind natural processes of the Earth.
Application of physics to study the Earth.

23. What does your A-level have do with geophysics?
27/04/2019
What does your A-level have do with geophysics?
Seismology
Satellite, GPS
Material properties and stress-strain graphs
Gravitational field strength
Hooke’s law and Young’s Modulus
Properties of light
Gravitational methods
Elastic strain and strain energy
Newton’s laws
Waves, polarisation, reflection, refraction and diffraction
Radar
Vector analysis of motion
Volcanology, Atmospheric
Electromagnetic Methods
Fluid flow, laws of motion
Electric circuits and resistivity
Stoke’s law, density and viscosity
Magnetism and electromagnetism

24. Electromagnetic SurveyingEM
27/04/2019
Electromagnetic Surveying
Like the common “metal detector”
Uses an ultra-low-frequency radio transmitter (e.g. 10kHz)
Transmit a known “primary” signal, measure the response.
The difference between what was transmitted and what is measured depends on the properties of the subsurface e.g. conductivity.

25. EM
27/04/2019
Landfills

26. Building foundations and contaminantsEM
27/04/2019
Building foundations and contaminants

27. EM
27/04/2019
Can be used for detecting aquifers, contaminants, landfills, archaeology, oil and gas, ore bodies.
Work horse of EM surveying, can see deep and is very quick and cheap.
Can be mounted to people, cars, trains, planes, ships...

28. Ground penetrating radar
GPR
27/04/2019
Ground penetrating radar
Emit pulses of radio waves and measure the time taken for them to reflect off the subsurface and return to the sensor.
Uses frequencies of 25MHz – 1GHz.
The speed that radio waves travel in a material is governed by the dielectric permittivity – similar to conductivity.
Like EM can mount equipment to pretty much anything...

29. GPR “Recent” technique developed since 1960s.
27/04/2019
“Recent” technique developed since 1960s.
Good for glaciology, UXO detection, forensic investigations, construction, utility surveying, archaeology.
Depth of survey decreases as frequency increases – attenuation.
Resolution increases with frequency however.

30. Radar Not GPR but Radar - SRTM Shuttle Radar Topography Mission
27/04/2019
Not GPR but Radar - SRTM Shuttle Radar Topography Mission
Extendable boom built onto space shuttle with radar transmitter on the end.
Send out radio pulses which reflect off Earth’s surface to map topography.
Best maps of remote regions available still.

31. InSAR Like other satellite radar uses lower frequencies than GPR.
27/04/2019
Like other satellite radar uses lower frequencies than GPR.
Take radar measurements repeatedly over the same area, calculate the difference between each pass of the satellite.
Used to monitor deformation of the Earth by volcanoes and earthquakes.
An interferogram - the different colour bands represent 3cm changes in the distance between the satellite and the ground.

32. Spontaneous Potential
27/04/2019
Spontaneous Potential
Oldest and simplest form of geophysical surveying.
Place one fixed electrode and move another, measure the voltage but input no current.
Naturally currents flow through the Earth – generated by magnetic field of Earth.
Think circuits – current takes path of least resistance so is concentrated in conductive bodies and is not constant everywhere.
Small differences but visible on large scales e.g. ore bodies.
Can measure flow direction underground.
-ve
+ve

33. IP Induced Polarisation
27/04/2019
Induced Polarisation
Between resistivity and SP surveying – induce a current into the ground then switch off and measure response.
Time it takes for charge to build and dissipate depends on the conductivity of subsurface materials.
Very simple fieldwork, 4 electrodes like resistivity but no moving.
Particularly effective for saline fluids and disseminated metal ores.
Voltage
Time
Earth acts like a capacitor

34. Summary
27/04/2019
Generally:
Sensitive to EM properties, therefore fluids and metals common targets.
Non-invasive – do not disturb ground and leave no trace, some don’t even touch ground.
Quick, cheap and quiet.
Best for relatively shallow surveys.
Mobile, can be carried out from ground, air, sea or space.
High conductivity/low resistivity reduces penetration.
Therefore some are useless over water or waterlogged ground or volcanic deposits...but not ice.
What methods might you use to...
Find a plastic or a metal utility pipe?
Find disturbed ground at a crime scene?
Find an aquifer?
Find a metal ore deposit?