[Janssen] Fault zone damage and chemical reactions at depth in the San Andreas Fault Zone: A study of SAFOD drill core samples
German Title: Fault zone damage and chemical reactions at depth in the San Andreas Fault Zone: A study of SAFOD drill core samples
Abbreviation: 256
Current Status: completed
Main Applicant:Dr. Christoph Janssen
Resources Recipient
Other Persons
Prof. Dr. Georg Dresen
Conveyor
Begin:
Conveyor
End:
Conveyor
Duration:
Year: 2009
Description
Our research project was structured around a series of questions addressing some basic issues in fault dynamics. The central scientific question was “Why are the San Andreas and some other major faults absolutely or relatively weak?" In response to this question several deformation mechanisms (e.g. amorphous material, nano-scale pore spaces, dissolutionprecipitation processes, intracrystalline plasticity), operating in the fault gouge of SAFOD core samples, were successfully analyzed using TEM, SEM and microprobe analyses. Amorphous material and nano-scale pore spaces were proofed as possible weakening mechanisms. Furthermore and in agreement with previous studies we also suggest that the high amount of weak clay minerals in general and the growth of Mg-rich phyllosilicates in particular may play a key role in the mechanical behavior of the San Andreas fault and can be directly related to fault weakening. The presence of abundant clay minerals is often related to the occurrence of nano-scale porosity that may indicates high fluid pressure. However, the SAFOD borehole was drilled into a creeping (aseismic) portion of the San Andreas Fault. The mechanisms relating earthquakes and aseismic creep remain still elusive due to the absence of microstructures that enable the evaluation of coseismic slip in SAFOD core samples. So, the inclusion of TCDP and Nojima fault drilling samples enabled us to identify key similarities and differences between characteristic microstructures of slip zones recently formed by co-seismic processes in earthquake faults (TCDP; Nojima fault) and active but aseismic creep that is evident in the SAFOD borehole by pronounced and ongoing casing deformation.
Related Publications
Janssen, C., Wirth, R., Wenk, H. R., Morales, L., Naumann, R., Kienast, M., Song, S. R., Dresen, G. (2014). "Faulting processes in active faults – Evidences from TCDP and SAFOD drill core samples" Journal of Structural Geology p100-116
Janssen, C., Kanitpanyacharoen, W., Wenk, H. R., Wirth, R., Morales, L., Rybacki, E., Kienast, M., Dresen, G. (2012). "Clay fabrics in SAFOD core samples" Journal of Structural Geology p118-127
Rybacki, E., Janssen, C., Wirth, R., Chen, K., Wenk, H. R., Stromeyer, D., Dresen, G. (2011). "Low-temperature deformation in calcite veins of SAFOD core samples (San Andreas Fault) — Microstructural analysis and implications for fault rheology" Tectonophysics 509 p107-119
Wenk, Hans-Rudolf, Janssen, Christoph, Kenkmann, Thomas, Dresen, Georg (2011). "Mechanical twinning in quartz: Shock experiments, impact, pseudotachylites and fault breccias" Tectonophysics 510 p69-79
Janssen, Christoph, Wirth, Richard, Reinicke, Andreas, Rybacki, Erik, Naumann, Rudolf, Wenk, Hans-Rudolf, Dresen, Georg (2011). "Nanoscale porosity in SAFOD core samples (San Andreas Fault)" Earth and Planetary Science Letters 301 p179-189
Janssen, C., Wirth, R., Rybacki, E., Naumann, R., Kemnitz, H., Wenk, H. R., Dresen, G. (2010). "Amorphous material in SAFOD core samples (San Andreas Fault): Evidence for crush-origin pseudotachylytes?" Geophysical Research Letters 37 pL01303