Location

Location ANSS

2017/06/06 00:12:03 59.142 -136.324 5.3 3.5 Alaska

Focal Mechanism

USGS/SLU Moment Tensor Solution ENS 2017/06/06 00:12:03:0 59.14 -136.32 5.3 3.5 Alaska Stations used: AK.BCP AK.BESE AK.JIS AK.KIAG AT.SKAG CN.HYT CN.YUK2 CN.YUK4 CN.YUK5 CN.YUK6 CN.YUK7 TA.M29M TA.M30M TA.M31M TA.N30M TA.N31M TA.N32M TA.O28M TA.O29M TA.O30N TA.P29M TA.P30M TA.P32M TA.P33M TA.Q32M TA.R31K TA.R32K TA.R33M TA.S31K TA.S32K Filtering commands used: cut o DIST/3.3 -30 o DIST/3.3 +40 rtr taper w 0.1 hp c 0.03 n 3 lp c 0.07 n 3 Best Fitting Double Couple Mo = 2.48e+21 dyne-cm Mw = 3.53 Z = 17 km Plane Strike Dip Rake NP1 128 51 98 NP2 295 40 80 Principal Axes: Axis Value Plunge Azimuth T 2.48e+21 82 82 N 0.00e+00 6 303 P -2.48e+21 5 212 Moment Tensor: (dyne-cm) Component Value Mxx -1.77e+21 Mxy -1.10e+21 Mxz 2.45e+20 Myy -6.42e+20 Myz 4.79e+20 Mzz 2.41e+21 -------------- ---------------------- ---------------------------- ------------------------------ #--#################-------------- #-#######################----------- ---##########################--------- ----############################-------- -----#############################------ ------################# ##########------ -------################ T ###########----- --------############### ############---- ----------#############################--- ----------############################-- ------------###########################- --------------######################## ---------------##################### ------------------################ ------------------------------ --- ---------------------- P ------------------- -------------- Global CMT Convention Moment Tensor: R T P 2.41e+21 2.45e+20 -4.79e+20 2.45e+20 -1.77e+21 1.10e+21 -4.79e+20 1.10e+21 -6.42e+20 Details of the solution is found at http://www.eas.slu.edu/eqc/eqc_mt/MECH.NA/20170606001203/index.html

Preferred Solution

The preferred solution from an analysis of the surface-wave spectral amplitude radiation pattern, waveform inversion and first motion observations is

      STK = 295
      DIP = 40
     RAKE = 80
       MW = 3.53
       HS = 17.0

The NDK file is 20170606001203.ndk The waveform inversion is preferred.

Moment Tensor Comparison

The following compares this source inversion to others

SLU

USGS/SLU Moment Tensor Solution ENS 2017/06/06 00:12:03:0 59.14 -136.32 5.3 3.5 Alaska Stations used: AK.BCP AK.BESE AK.JIS AK.KIAG AT.SKAG CN.HYT CN.YUK2 CN.YUK4 CN.YUK5 CN.YUK6 CN.YUK7 TA.M29M TA.M30M TA.M31M TA.N30M TA.N31M TA.N32M TA.O28M TA.O29M TA.O30N TA.P29M TA.P30M TA.P32M TA.P33M TA.Q32M TA.R31K TA.R32K TA.R33M TA.S31K TA.S32K Filtering commands used: cut o DIST/3.3 -30 o DIST/3.3 +40 rtr taper w 0.1 hp c 0.03 n 3 lp c 0.07 n 3 Best Fitting Double Couple Mo = 2.48e+21 dyne-cm Mw = 3.53 Z = 17 km Plane Strike Dip Rake NP1 128 51 98 NP2 295 40 80 Principal Axes: Axis Value Plunge Azimuth T 2.48e+21 82 82 N 0.00e+00 6 303 P -2.48e+21 5 212 Moment Tensor: (dyne-cm) Component Value Mxx -1.77e+21 Mxy -1.10e+21 Mxz 2.45e+20 Myy -6.42e+20 Myz 4.79e+20 Mzz 2.41e+21 -------------- ---------------------- ---------------------------- ------------------------------ #--#################-------------- #-#######################----------- ---##########################--------- ----############################-------- -----#############################------ ------################# ##########------ -------################ T ###########----- --------############### ############---- ----------#############################--- ----------############################-- ------------###########################- --------------######################## ---------------##################### ------------------################ ------------------------------ --- ---------------------- P ------------------- -------------- Global CMT Convention Moment Tensor: R T P 2.41e+21 2.45e+20 -4.79e+20 2.45e+20 -1.77e+21 1.10e+21 -4.79e+20 1.10e+21 -6.42e+20 Details of the solution is found at http://www.eas.slu.edu/eqc/eqc_mt/MECH.NA/20170606001203/index.html

Magnitudes

ML Magnitude

(a) ML computed using the IASPEI formula for Horizontal components; (b) ML residuals computed using a modified IASPEI formula that accounts for path specific attenuation; the values used for the trimmed mean are indicated. The ML relation used for each figure is given at the bottom of each plot.

(a) ML computed using the IASPEI formula for Vertical components (research); (b) ML residuals computed using a modified IASPEI formula that accounts for path specific attenuation; the values used for the trimmed mean are indicated. The ML relation used for each figure is given at the bottom of each plot.

Context

The next figure presents the focal mechanism for this earthquake (red) in the context of other events (blue) in the SLU Moment Tensor Catalog which are within ± 0.5 degrees of the new event. This comparison is shown in the left panel of the figure. The right panel shows the inferred direction of maximum compressive stress and the type of faulting (green is strike-slip, red is normal, blue is thrust; oblique is shown by a combination of colors).

Waveform Inversion using wvfgrd96

The focal mechanism was determined using broadband seismic waveforms. The location of the event and the and stations used for the waveform inversion are shown in the next figure.

Location of broadband stations used for waveform inversion

The program wvfgrd96 was used with good traces observed at short distance to determine the focal mechanism, depth and seismic moment. This technique requires a high quality signal and well determined velocity model for the Green functions. To the extent that these are the quality data, this type of mechanism should be preferred over the radiation pattern technique which requires the separate step of defining the pressure and tension quadrants and the correct strike.

The observed and predicted traces are filtered using the following gsac commands:

cut o DIST/3.3 -30 o DIST/3.3 +40
rtr
taper w 0.1
hp c 0.03 n 3 
lp c 0.07 n 3

The results of this grid search from 0.5 to 19 km depth are as follow:

           DEPTH  STK   DIP  RAKE   MW    FIT
WVFGRD96    1.0    25    65    15   3.16 0.3447
WVFGRD96    2.0    45    45   -90   3.24 0.4019
WVFGRD96    3.0   115    65   -25   3.34 0.3780
WVFGRD96    4.0    30    80   -30   3.37 0.3525
WVFGRD96    5.0   185    30   -10   3.35 0.3691
WVFGRD96    6.0   170    25   -30   3.36 0.4055
WVFGRD96    7.0   160    25   -45   3.37 0.4385
WVFGRD96    8.0   150    20   -50   3.44 0.4586
WVFGRD96    9.0   150    25   -60   3.46 0.4883
WVFGRD96   10.0   150    30   -65   3.48 0.5122
WVFGRD96   11.0   115    60    75   3.47 0.5330
WVFGRD96   12.0   120    55    85   3.49 0.5594
WVFGRD96   13.0   300    40    85   3.50 0.5811
WVFGRD96   14.0   300    40    85   3.51 0.5982
WVFGRD96   15.0   125    50    95   3.51 0.6084
WVFGRD96   16.0   125    50    95   3.52 0.6135
WVFGRD96   17.0   295    40    80   3.53 0.6142
WVFGRD96   18.0   290    40    75   3.53 0.6116
WVFGRD96   19.0   290    40    75   3.54 0.6061
WVFGRD96   20.0   285    40    75   3.54 0.5981
WVFGRD96   21.0   285    40    75   3.55 0.5889
WVFGRD96   22.0   285    40    70   3.56 0.5776
WVFGRD96   23.0   285    40    70   3.56 0.5649
WVFGRD96   24.0   280    40    65   3.57 0.5512
WVFGRD96   25.0   280    40    65   3.57 0.5370
WVFGRD96   26.0   275    40    60   3.58 0.5219
WVFGRD96   27.0   275    40    60   3.58 0.5063
WVFGRD96   28.0   275    40    60   3.59 0.4898
WVFGRD96   29.0   285    35    70   3.59 0.4731

The best solution is

WVFGRD96   17.0   295    40    80   3.53 0.6142

The mechanism correspond to the best fit is

Figure 1. Waveform inversion focal mechanism

The best fit as a function of depth is given in the following figure:

Figure 2. Depth sensitivity for waveform mechanism

The comparison of the observed and predicted waveforms is given in the next figure. The red traces are the observed and the blue are the predicted. Each observed-predicted component is plotted to the same scale and peak amplitudes are indicated by the numbers to the left of each trace. A pair of numbers is given in black at the right of each predicted traces. The upper number it the time shift required for maximum correlation between the observed and predicted traces. This time shift is required because the synthetics are not computed at exactly the same distance as the observed and because the velocity model used in the predictions may not be perfect. A positive time shift indicates that the prediction is too fast and should be delayed to match the observed trace (shift to the right in this figure). A negative value indicates that the prediction is too slow. The lower number gives the percentage of variance reduction to characterize the individual goodness of fit (100% indicates a perfect fit).

The bandpass filter used in the processing and for the display was

cut o DIST/3.3 -30 o DIST/3.3 +40
rtr
taper w 0.1
hp c 0.03 n 3 
lp c 0.07 n 3

Figure 3. Waveform comparison for selected depth. Red: observed; Blue - predicted. The time shift with respect to the model prediction is indicated. The percent of fit is also indicated.

Focal mechanism sensitivity at the preferred depth. The red color indicates a very good fit to thewavefroms. Each solution is plotted as a vector at a given value of strike and dip with the angle of the vector representing the rake angle, measured, with respect to the upward vertical (N) in the figure.

A check on the assumed source location is possible by looking at the time shifts between the observed and predicted traces. The time shifts for waveform matching arise for several reasons:

The origin time and epicentral distance are incorrect
The velocity model used for the inversion is incorrect
The velocity model used to define the P-arrival time is not the same as the velocity model used for the waveform inversion (assuming that the initial trace alignment is based on the P arrival time)

Assuming only a mislocation, the time shifts are fit to a functional form:

 Time_shift = A + B cos Azimuth + C Sin Azimuth

The time shifts for this inversion lead to the next figure:

The derived shift in origin time and epicentral coordinates are given at the bottom of the figure.

Discussion

Acknowledgements

Thanks also to the many seismic network operators whose dedication make this effort possible: University of Nevada Reno, University of Alaska, University of Washington, Oregon State University, University of Utah, Montana Bureas of Mines, UC Berkely, Caltech, UC San Diego, Saint Louis University, University of Memphis, Lamont Doherty Earth Observatory, the Iris stations and the Transportable Array of EarthScope.

Velocity Model

The WUS.model used for the waveform synthetic seismograms and for the surface wave eigenfunctions and dispersion is as follows:

MODEL.01
Model after     8 iterations
ISOTROPIC
KGS
FLAT EARTH
1-D
CONSTANT VELOCITY
LINE08
LINE09
LINE10
LINE11
      H(KM)   VP(KM/S)   VS(KM/S) RHO(GM/CC)         QP         QS       ETAP       ETAS      FREFP      FREFS
     1.9000     3.4065     2.0089     2.2150  0.302E-02  0.679E-02   0.00       0.00       1.00       1.00    
     6.1000     5.5445     3.2953     2.6089  0.349E-02  0.784E-02   0.00       0.00       1.00       1.00    
    13.0000     6.2708     3.7396     2.7812  0.212E-02  0.476E-02   0.00       0.00       1.00       1.00    
    19.0000     6.4075     3.7680     2.8223  0.111E-02  0.249E-02   0.00       0.00       1.00       1.00    
     0.0000     7.9000     4.6200     3.2760  0.164E-10  0.370E-10   0.00       0.00       1.00       1.00

Quality Control

Here we tabulate the reasons for not using certain digital data sets

The following stations did not have a valid response files:

Last Changed Tue Jun 6 04:38:14 CDT 2017