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Seismic wave propagation through surface basalts - implications for coal seismic surveys  

Sun, Weijia (CSIRO Exploration and Mining)
Zhou, Binzhong (CSIRO Exploration and Mining)
Hatherly, Peter (Coalbed Geoscience Pty Ltd)
Fu, Li-Yun (Institute of Geology and Geophysics, Chinese Academy of Sciences)
Publication Information
Geophysics and Geophysical Exploration / v.13, no.1, 2010 , pp. 1-8 More about this Journal
Abstract
Seismic reflection surveying is one of the most widely used and effective techniques for coal seam structure delineation and risk mitigation for underground longwall mining. However, the ability of the method can be compromised by the presence of volcanic cover. This problem arises within parts of the Bowen and Sydney Basins of Australia and seismic surveying can be unsuccessful. As a consequence, such areas are less attractive for coal mining. Techniques to improve the success of seismic surveying over basalt flows are needed. In this paper, we use elastic wave-equation-based forward modelling techniques to investigate the effects and characteristics of seismic wave propagation under different settings involving changes in basalt properties, its thickness, lateral extent, relative position to the shot position and various forms of inhomogeneity. The modelling results suggests that: 1) basalts with high impedance contrasts and multiple flows generate strong multiples and weak reflectors; 2) thin basalts have less effect than thick basalts; 3) partial basalt cover has less effect than full basalt cover; 4) low frequency seismic waves (especially at large offsets) have better penetration through the basalt than high frequency waves; and 5) the deeper the coal seams are below basalts of limited extent, the less influence the basalts will have on the wave propagation. In addition to providing insights into the issues that arise when seismic surveying under basalts, these observations suggest that careful management of seismic noise and the acquisition of long-offset seismic data with low-frequency geophones have the potential to improve the seismic results.
Keywords
coal seam; finite difference; forward modelling; inhomogeneity; long-offset recording; low frequencies; sub-basalt imaging;
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  • Reference
1 Christie, P. A. F., and White, R. S., 2008, Imaging through Altantic Margin basalts: An introduction to the sub-basalt min-set: Geophysical Prospecting, 56, 1–4.
2 Fruehn, J., Fliedner, M. M., and White, R. S., 2001, Integrated wide-angle and near-vertical sub-basalt study using large-aperture seismic data from the Faeroe-Shetland region: Geophysics, 66, 1340–1348. doi:10.1190/1.1487079
3 Hobbs, R., 2002, Sub-basalt imaging using low frequencies: Journal of Conference Abstracts, 7, 152–153.
4 Virieux, J., 1986, P-SV wave propagation in heterogeneous media: Velocitystress finite-difference method: Geophysics, 51, 889–901. doi:10.1190/1.1442147
5 Gallagher, J. W., and Dromgoole, P. W., 2008, Seeing below the basalt –offshore Faroes: Geophysical Prospecting, 56, 33–45.
6 Ziolkowski, A., Hanssen, P., Gatliff, R., Li, X., and Jakubowicz, H., 2001, The use of low frequencies for sub-basalt imaging: 71st Annual International Meeting Society Exploration Geophysics Expanded Abstracts, 74–78.
7 Fruehn, J., Sugrue, M., and Emsley, D., 1999, Sub-basalt imaging improvements – west of Hebrides: 69th Annual International Meeting Society Exploration Geophysics Expanded Abstracts, 1084–1088.
8 Ryu, J. V., 1997, Seeing through seismically difficult rocks unconventionally: Geophysics, 62, 1177–1182. doi:10.1190/1.1444218
9 Samson, C., Barton, P., and Karwatowski, J., 1995, Imaging below an opaque basaltic layer using densely sampled wide angle OBS data: Geophysical Prospecting, 43, 509–527. doi:10.1111/j.1365-2478.1995.tb00264.x
10 Lau, K. W. H., White, R. S., and Christie, P. A. F., 2007, Low-frequency source for long-offset, sub-basalt and deep crustal penetration: Leading Edge, 26, 36–39. doi:10.1190/1.2431830
11 Spitzer, R., White, R. S., and Christie, P. A. E., 2008, Seismic characterization of basalt flows from the Faroes margin and the Faroe-Shetland Basin: Geophysical Prospecting, 56, 21–31.
12 Hanssen, P., Ziolkowski, A., and Li, X., 2003,Aquantitative study on the use of converted waves for sub-basalt imaging: Geophysical Prospecting, 51, 183–193. doi:10.1046/j.1365-2478.2003.00367.x
13 Behera, L., 2006, Sub-basalt imaging using converted waves: A numerical approach: 76th Annual International Meeting Society Exploration Geophysics Expanded Abstracts, 2318–2322.
14 Battig, E., and Hearn, S., 2001, Numerical modelling of seismic reflection in basalt terrains: Extended Abstract of ASEG 15th Geophysical Conference and Exhibition, Brisbane, 5–8 August.
15 Fruehn, J., White, R. S., Richardson, K. R., Fliedner, M., Cullen, E., Latkiewicz, C., Kirk, W., and Smallwood, J. R., 1998, Flare – a twoship experiment designed for sub-basalt imaging: 68th Annual International Meeting Society Exploration Geophysics Expanded Abstracts, 94–97.
16 Collino, F., and Tsogka, C., 2001, Application of the perfectly matched absorbing layer model to the linear elastodynamic problem in anisotropic heterogeneous media: Geophysics, 66, 294–307. doi:10.1190/1.1444908
17 Reshef, M., Shulman, H., and Ben-Avraham, Z., 2003, A case study of sub-basalt imaging in land region covered with basalt flows: Geophysical Prospecting, 51, 247–260. doi:10.1046/j.1365-2478.2003.00368.x
18 Fliedner, M. M., and White, R. S., 1999, Using wide-angle seismic data for basalt and sub-basalt imaging: 69th Annual International Meeting Society Exploration Geophysics Expanded Abstracts, 1021–1025.
19 Hu, Z., Wu, D., and Guan, L., 2003, Wide-angle seismic imaging of the high-velocity sub-basalt: 73th Annual International Meeting Society Exploration Geophysics Expanded Abstracts, 1142–1145.
20 Papworth, T. J., 1985, Seismic exploration over basalt covered areas in the UK: First Break, 3, 20–32.
21 Wombell, R., Jones, E., Priestly, D., and Williams, G., 1999, Long offset acquisition and processing for sub-basalt imaging: 69th Annual International Meeting Society Exploration Geophysics Expanded Abstracts, 1429–1432.
22 Williamson, P., 2003, Introduction: Geophysical Prospecting, 51, 167–168. doi:10.1046/j.1365-2478.2003.00378.x
23 Ikelle, L. T., Yung, S. K., and Daube, F., 1993, 2-d random media with ellipsoidal autocorrelation functions: Geophysics, 58, 1359–1372. doi:10.1190/1.1443518
24 Mittet, R., 2002, Free-surface boundary conditions for elastic staggered-grid modeling schemes: Geophysics, 67, 1616–1623. doi:10.1190/1.1512752