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1 Royal Netherlands Meteorological
Institute
Seismology Division
P.O. Box 201
3730 AE De Bilt, The Netherlands
evers{at}knmi.nl,
haak{at}knmi.nl
(L.G.E,
H.W.H.)
2 Bundesanstalt
für
Geowissenschaften und Rohstoffe
Stilleweg 2
D-30655 Hannover, Germany
ceranna{at}sdac.hannover.bgr.de
(L.C.)
3 Commissariat
à
l’Energie
Atomique
B.P. 12
91680 Bruyeres-Le-Chatel, France
alexis.le-pichon{at}cea.fr
(A.L.P.)
4 Los Alamos National
Laboratory
P.O. Box 1663
Los Alamos, New Mexico 87545
rww{at}lanl.gov
(R.W.W.)
A high-pressure gas pipeline exploded near Ghislenghien in Belgium, on 30 July 2004. Seismic energy of this event was recorded at three nearby seismometers. The origin time of the explosion was determined by analyzing the Rayleigh waves and found to be 06h55m27±2sec coordinated universal time (UTC). Ground truth of the explosion was invoked to assess the accuracy of the location derived from infrasound data recorded over Western Europe. Different infrasonic phases were identified by using array-processing techniques and raytracing through atmospheric models. The analysis showed that the derived location was situated 13 km from the true location. The total area of the uncertainty ellipse, or area to be searched if the source was of unknown origin, was 690 km2. After the origin time and location, the yield was calculated by comparing infrasonic stratospheric amplitudes with those from a high-explosives dataset and was estimated at 40.9 tons high- explosives equivalent. In summary, this study illustrates the capability of seismic and infrasound data in forensic investigations. Furthermore, the potential of infrasound as a monitoring or verification technique is addressed.
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