Focal mechanisms and moment tensors of micro-earthquakes in the Malé Karpaty (Little Carpathians) Mts., Slovakia Lucia Fojtíková 1, Václav Vavryčuk 2,

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Focal mechanisms and moment tensors of micro-earthquakes in the Malé Karpaty (Little Carpathians) Mts., Slovakia Lucia Fojtíková 1, Václav Vavryčuk 2, Miriam Kristeková 1 1) Geophysical Institute, Slovak Academy of Sciences, Bratislava, 2) Institute of Geophysics, Academy of Sciences of the Czech Republic, Prague AIM – Bratislava, 2010 Abstract: We have analyzed selected micro-earthquakes with magnitudes between 1.2 and 3.4 that occurred in the Malé Karpaty Mts., Slovakia, within the period of Three different methods were used to calculate the focal mechanisms: (a) a method using the polarities of Pg and Pn waves, (b) the P-wave amplitude inversion of moment tensors and (c) the waveform inversion of moment tensors. We have compared the three methods from the point of view of their sensitivity to the quality and amount of input data and accuracy of the structural model as well as from the point of view of their computational efficiency. All three methods show similar double-couple parts of the focal mechanisms, however the moment tensors comprise significant non-double-couple components. A detailed time-frequency analysis of seismic signals was used to identify an appropriate frequency interval for the waveform inversion of the moment tensors. We have investigated a possible influence of non-optimal choice of the frequency interval on the obtained results, in particular, on the stability of the double-couple and non-double-couple components of the moment tensors. Velocity Model and Locations P-wave velocities in the 1-D layered (dashed line) and gradient (solid line) models. The local seismic network consists of 11 stations equipped with short- period SM-3, Le3D or CMG-40T-1 sensors. The sampling frequency is 100 Hz. Focal Mechanisms and Moment Tensors Focal mechanisms from the P-wave polarities (program FOCMEC, Snoke 2003) - local as well as regional stations - predominant frequencies of 5-10 Hz - gradient medium model - take-off angles calculated by ray tracing Full moment tensors from the P-wave amplitudes (program AMT, Vavryčuk 2008) - at least 8 local stations - P waves with predominant frequencies of Hz - smooth gradient medium model - Green’s functions calculated using the ray method Full moment tensors from complete seismograms (program ISOLA, Sokos & Zahradník 2009) Parameters used for comparison of the results of 44 events - waveforms from 3 to 5 nearest local seismic stations - layered medium model - Green’s functions calculated using the DWN method (Countant 1990) - band-pass filter in the frequency range of 0.8 – 1.6 Hz - for the selected events the influence of the choice of the frequency range for the inversion was investigated using the time-frequency analysis The majority of mechanisms have the P axes clustered in the NE direction. Focal mechanisms inverted from waveforms of one station and of three stations are similar. Different suitably chosen frequency ranges of inversion provided consistent results. Including of higher frequencies, however, decreased degree of similarity of the synthetic and observed waveforms (e.g. for the range up to 5 Hz: often too low). This emphasizes the importance of the sufficient knowledge of the velocity model. Different degree of similarity for the same event and various stations also in their TFRs indicates significant lateral variations in the velocity model in this region. In the case of imprecise knowledge of the model, computation of the focal mechanisms and moment tensors using different methods with different input data can provide independent solutions and their consistency can validate the results of the inversions. Time-Frequency Analysis Continuous Wavelet Transform (program RCWT, Kristekova 2006) - time-frequency representations (TFRs) for each earthquake record used for waveform inversion was computed using the Continuous Wavelet Transform (CWT) with the Morlet wavelet (ω 0 =6) - three frequency intervals for waveform inversion were selected based on TFRs ( Hz, Hz, Hz), upper frequency limit was set to 5 Hz due to lower accuracy of the velocity model at higher frequencies, lower frequency limit was selected taking into account the energy content of the signals and the equipment used at the stations stationazimuth [°]distance [km] SMO KAT DVO HRA V14, Ml = 2.2, h = 5.2 km Observed waveform Synthetic waveform Waveform inversion for event V14: a comparison of synthetic (red line) and observed (black line) waveforms at stations KAT, DVO and HRA. Waveform inversion from records of 3 stations: KAT, DVO and HRA band-pass filter Hz band-pass filter Hz Waveform inversion from records of 1 station: SMO band-pass filter Hz band-pass filter Hz band-pass filter Hz Nodal lines and P/T axes of focal mechanisms determined for different frequency ranges - several events were processed with TFA - here we show a parametric study with event V14 Nodal lines and P/T axes of the focal mechanisms determined from the P-wave polarities (FOCMEC), moment tensors determined from the P-wave amplitudes (AMT), and moment tensors determined from the complete waveforms (ISOLA). The P-axes are marked by red circles and the T-axes are marked by blue plus signs. The lower-hemisphere equal-area projection is used. N =36 N =16 N = 38 AMT ISOLA FOCMEC Comparison of the results of three methods (for 44 events) SMO Frequency [Hz] Time [s] Frequency [Hz] KAT Time [s] T P V14 T P T P References Coutant, O., Program of numerical simulation AXITRA. Laboratoire de Géophysique Interne et Tectonophysique Report, University of Joseph Fourier. Kristekova, M. et al, SEIS-TFA, the source code in Fortran 95 and Users‘ guide. (developed within Ph.D. Thesis) Available from Snoke, J. A., FOCMEC: Focal Mechanism determinations. International Handbook of Earthquake and Engineering Seismology (W.H.K. Lee, H. Kanamori, P.C. Jennings and C. Kisslinger, Eds.), Academic Press, San Diego, Chapter Sokos, E., Zahradník, J., ISOLA – A Fortran code and Matlab GUI to perform multiplepoint source inversion of seismic data. Comput. Geosci. 34, Vavryčuk, V., Inversion for parameters of tensile earthquakes. J. Geophys. Res. 106, Vavryčuk, V., Amplitude inversion of moment tensors – program AMT. Inst. Geophysics, Prague. ZZNNEE