1. Physical interpretation of DC and non-DC components of moment tensors Václav Vavryčuk Institute of Geophysics, Prague

2. MT for simple types of seismic sources

3. Explosive (implosive) source
Source process
Force equivalent
Moment tensor
explosion
three linear
dipoles
implosion

4. Shear faulting Source process Force equivalent Moment tensor no torque
double-couple
(quadrupole)

5. Pure tensile faulting Source process Force equivalent Moment tensor
opening
fault opening
closing

6. Shear-tensile faulting
Source process
Force equivalent
Moment tensor
DC +
fault
opening
fault opening
closing

7. Decomposition of MT

8. Decomposition of MT + +
ISO DC
CLVD
non-shear
shear
non-shear

9. Double-couple component of the moment tensor
Force equivalent
Seismic moment tensor
DC part
double couple (DC)
(shear faulting)
rotated double-couple (DC)

10. Non-double couple components: ISO and CLVD
Force equivalent
Seismic moment tensor
ISO part
(explosion)
CLVD part
(tensile crack)
compensated linear vector dipole

11. Decomposition of the moment tensor
M – moment tensor
MISO – trace of M
M* – deviatoric part of M
Percentage of ISO, CLVD and DC : |ISO|+|CLVD|+DC = 100%

12. Physical interpretation of MT

13. Parameters of shear faulting
DC components
Parameters of shear faulting
orientation of active faults, fault mapping
type of fracturing (strike-slip, normal/reverse faulting)
Determination of present-day tectonic stress
orientation of principal stress axes
ratio between principal stresses

14. Numerical errors of the MT inversion
insufficient number of stations
presence of noise in the data
unfavourable station coverage of the focal sphere
inaccurate knowledge of the structure model
approximate location and Green’s functions
approximate moment tensor

15. Presence of single forces
no dipole forces
Examples: impact of meteorites, landslides, volcanic eruptions, fluid flow in volcanic channels
the process is not described by the moment tensor!

16. Complex shear faulting
DC1
DC2
DC + CLVD
ISO = 0
fault
Sum of two DCs of different orientations produces DC and CLVD

17. Combined shear-tensile faulting I
DC + CLVD + ISO
fault
Example: hydrofracturing
High pore pressure can cause opening faults during the rupture process (CLVD and ISO are then positive).

18. Combined shear-tensile faulting II
CLVD and ISO are correlated!
ISO/CLVD -> vP/vS

19. Correlation between ISO and CLVD
shear-tensile faulting
linear dependence
different vP/vS ratios
CLVD [%]

20. Shear faulting in anisotropic media
DC + CLVD + ISO
fault
The relation between fracture geometry and acting forces is more complicated in anisotropic media than in isotropic media.

21. Moment tensors in isotropy
Shear earthquakes in isotropy
(Aki & Richards 2002, Eq. 3.22): n S un
u – slip
S – fault area
 – shear modulus
 – slip direction
n – fault normal
cijkl – elastic parameters
double-couple (DC) mechanism

22. Moment tensors in anisotropy
Shear earthquakes in anisotropy
(Aki & Richards 2002, Eq. 3.19): n S un
u – slip
S – fault area
 – shear modulus
 – slip direction
n – fault normal
cijkl – elastic parameters
general (non-DC) mechanism

23. Examples

24. 1997 West-Bohemian earthquake swarm

25. Example: seismicity in West Bohemia
active tectonics
geothermal area
mineral springs
emanations of CO2
earthquake swarms:
1985/86
1994
1997
2000
2008

26. Swarm 97: Basic characteristics
Duration: weeks
Number of earthquakes:
Strongest event: M=3.0
Depth of events: km
Focal area: x700x1000 m
Faults activated: 2 different faults N
P wave
S wave Z E
1 s

27. Swarm 97: epicentres and mechanisms
Nový Kostel focal area
Fischer & Horálek (2000)
Horálek et al. (2000)

28. DC & non-DC mechanisms
Type A
Type B

29. Correlation between ISO and CLVD
corr. coeff = 0.91 +
vP/vS = 1.48
strong indication for
tensile faulting!

30. Shear & tensile faulting
A events
B events
Shear faulting
Tensile faulting u u   
Slip is along the fault
Slip is not along the fault
Moment tensor is DC
Moment tensor is non-DC
(DC+CLVD+ISO)
 – fault , u – slip,  – deviation of the slip from the fault

31. Deviation of the slip from the fault
A events: -5 <  < 5
B events: 10 <  <20

32. Induced microseismicity during the 2000 fluid injection experiment in KTB, Germany

33. KTB superdeep drilling hole
location: northern Bavaria, Germany
holes: pilot hole - 4 km, main borehole km (October 1994), distance – 185 m
geology: crystalline unit, steeply inclined layers of gneisses, amphibolites
borehole geometry: vertical to 7.5 km, then inclined
bottom hole temperature: 265ºC N
P wave
S wave Z E
1 s

34. Injection experiment 2000 experiment: 60 days
amount of fluid: 4000 m3 of fresh water
entire 9.1 km borehole was pressurized
well head pressure was between 20 to 30 MPa
flow rate ranged between 30 to 70 l/min
several sharp pressure drops during shut-in phases N
P wave
S wave Z E
1 s

35. Focal mechanisms of 37 events
Nodal lines
P/T axes P T
Nodal lines and P/T axes are well clustered

36. Non-DC components ISO percentage CLVD percentage
Mean value of ISO = 1.5%
Mean value of CLVD = -5.7%
Positive values - tensile components, negative values - compressive components

37. Correlation between ISO and CLVD
corr. coeff. = 0.01
no correlation!
strong indication for
other origins than tensile faulting!

38. Anisotropy models at KTB
P-wave velocity
S-wave velocity
P anisotropy: %, S1 anisotropy: %, S2 anisotropy: %
anisotropic models of gneiss inferred from: VSP, sonic logs, lab measurements
References: Jahns et al. (1996), Rabbel (1994), Rabbel et al. (2004)

39. Inversion for anisotropy: method
Input:
moment tensors of 37 events
anisotropy at the focal area
Output:
fault normals and slip directions
theoretical DC, CLVD and ISO components
The misfit function: misfit between the theoretical and observed non-DC components
Result: optimum orientation of anisotropy

40. Inversion for anisotropy: results
Misfit for TI
Misfit for ORT
The misfit function is normalized so it equals 1 for an isotropic medium.

41. Optimum anisotropy orientation
Triangles:
optimum orientation from moment tensors
Squares:
orientation from MSP
Rabbel et al. (2004)
Anisotropy axes (plunge/azimuth):
Axis 1: 5º/65º, Axis 2: 50º/160º, Axis 3: 40º/330º

42. Summary

43. Significance of the DC components
Parameters of shear faulting
orientation of active faults, fault mapping
type of fracturing (strike-slip, normal/reverse faulting)
Determination of present-day tectonic stress
orientation of principal stress axes
ratio between principal stresses

44. Significance of the non-DC components
Discrimination explosions versus earthquakes
Analysis of tensile faulting
detection of overpressure regime
temporal variation of pore pressure
the vP/vS ratio in a focal area
Estimation of anisotropy in a focal area
orientation of anisotropy axes
anisotropy strength