Abstract
In March and April 1995 a cooperative German, Costa Rican, and United States research team recorded onshore-offshore seismic data sets along the Pacific margin of Costa Rica using the R/V Ewing. Off the Nicoya Peninsula we used a linear array of ocean bottom seismometers and hydrophones (OBS/H) with onshore seismometers extending across much of the isthmus. In the central area we deployed an OBS/H areal array consisting of 30 instruments over a 9 km by 35-km area and had land stations on the Nicoya Peninsula adjacent to this marine array and also extending northeast on the main Costa Rican landmass. Our goal in these experiments was to determine the crustal velocity structure along different portions of this convergent margin and to use the dense instrument deployments to create migrated reflection images of the plate boundary zone and the subducting Cocos Plate. Our specific goal in the central area was to determine whether a subducted seamount is present at the location of the 1990, M 7 earthquake off the Nicoya Peninsula and can thus be linked to its nucleation. Subsequently we have processed the data to improve reflection signals, used the data to calculate crustal velocity models, and developed several wide-aperture migration techniques, based on a Kirchhoff algorithm, to produce reflection images. Along the northern transect we used the ocean bottom data to construct a detailed crustal velocity model, but reflections from the plate boundary and top and bottom of the subducting Cocos plate are difficult to identify and have so far produced poor images. In contrast, the land stations along this same transect recorded clear reflections from the top of the subducting plate or plate boundary, within the seismogenic zone, and we have constructed a clear image from this reflector beneath the Nicoya shelf. Data from the 3-D seismic experiment suffer from high-amplitude, coherent noise (arrivals other than reflections), and we have tried many techniques to enhance the signal to noise ratio of reflected arrivals. Due to the noise, an apparent lack of strong reflections from the plate boundary zone, and probable structural complexity, the resulting 3-D images only poorly resolve the top of the subducting Cocos Plate. The images are not able to provide compelling evidence of whether there is a subducting seamount at the 1990 earthquake hypocenter. Our results do show that OBS surveys are capable of creating images of the plate boundary zone and the subducting plate well into the seismogenic zone if coherent reflections are recorded at 1.8 km instrument spacing (2-D) and 5 km inline by 1 km crossline spacing for 3-D acquisition. However, due to typical high amplitude coherent noise, imaging results may be poorer than expected, especially in unfavorable geologic settings such as our 3-D survey area. More effective noise reduction in acquisition, possibly with the use of vertical hydrophone arrays, and in processing, with advanced multiple removal and possibly depth filtering, is required to achieve the desired detailed images of the seismogenic plate boundary zone.
This is a preview of subscription content, log in via an institution to check access.
Similar content being viewed by others
References
Akbar, F.E., 1997, Three-dimensional prestack plane-wave Kirchhoff depth migration in laterally varying media, Ph.D. thesis, The University of Texas at Austin.
Akbar, F.E., Sen, M.K. and Stoffa, P.L., 1996, Pre-stack planewave Kirchhoff depth migration in laterally varying media, Geophysics 61: 1068–1097.
Buffler, R.T., 1982, Geologic structure of the forearc region off the west coast of Costa Rica in the vicinity of the Nicoya Peninsularesults of a multifold seismic reflection survey, U.T.I.G. Tech. Rep. 39, University of Texas at Austin Institute for Geophysics, 56 p.
Chang, W.-F., McMechan, G.A. and Keller, G.R., 1989, Wave field processing of data from a large-aperture seismic experiment in southwestern Oklahoma, J. Geophys. Res., 94: 1803–1816.
Chen, H.-W. and Chang, C.-W., 1998, Multiple suppression and subsurface imaging of OBS data, EOS, Trans. AGU (abstract), 79, 75.
Christeson, G.L., McIntosh, K.D., Shipley, T.H., Flueh, E. and Goedde, H. 1999, Structure of the Costa Rica convergent margin, offshore Nicoya Peninsula, J. Geophys. Res., 104: 25443–25468.
Cloos, M., 1992, Thrust-type subduction-zone earthquakes and seamount asperities; a physical model for seismic rupture, Geology, 20: 601–604.
Crowe, J.C. and Buffler, R.T., 1983, Regional seismic reflection profiles across the Middle America Trench and convergent margin of Costa Rica, in Studies in Geology Series, 153, in Bally A.W. (ed.), American Association of Petroleum Geologists, Tulsa, Okla, 3.4.2–147–3.4.2–162.
Engdahl, E.R. and Billington, S., 1986, Focal depth determination of central Aleutian earthquakes, Bull. Seismol. Soc. Am. 76: 77–93.
Flueh, E.R. and Bialas, J., 1996, A digital, high data capacity ocean bottom recorder for seismic investigations, Int. Underwater Systems Design 18: 18–20.
French, W.S., 1974, Two-dimensional and three-dimensional migration of model-experiment reflection profile, Geophysics 39: 265–277.
Hildebrand, S.T. and Carroll, R.J., 1993, Radon depth migration, Geophys. Prospecting 41: 229–240.
Hinz, K., von Huene, R. and Ranero, C.R., 1996, Tectonic structure of the convergent Pacific margin offshore Costa Rica from multichannel seismic reflection data, Tectonics 15: 54–66.
Holbrook, W.S., Reiter, E.C., Purdy, G.M. and Toksoz, M.N., Image of the Moho across the continent-ocean transition, U.S. east coast, 1992, Geology 20: 203–206.
Lafond, C.F., Levander, A., 1995, Migration of wide-aperture onshore-offshore seismic data, central California: Seismic images of late stage subduction, J. Geophys. Res. 100: 22231–22243.
McIntosh, K.D., Nakamura, Y., Flueh, E., Leandro, G. and TICOSECT participants, 1995, TICOSECT: Experiments to evaluate the crustal structure of the Costa Rica convergent margin, Eos, Transactions, AGU 76: 551.
McMechan, G.A. and Sun, R., 1991, Depth filtering of first breaks and ground roll, Geophysics 56: 390–396.
Milkereit, B., 1987, Migration of noisy crustal seismic data, J. Geophys. Res. 92: 7916–7930.
Moore, G.F., Shipley, T.H., Stoffa, P.L., Karig, D.E., Taira, A., Kuramoto, S., Tokuyama, H. and Suyehiro, K., 1990, Structure of the Nankai Trough accretionary zone from multichannel seismic reflection data, J. Geophys. Res. 95: 8753–8765.
Nabelek, J., Li, X.-Q., Azevedo, S., Braunmiller, J., Fabritius, A., Leitner, B., Trehu, A.M. and Zandt, G., 1993, A high-resolution image of the Cascadia subduction zone from teleseismic converted phases recorded by a broadband seismic array, Eos, Transactions, AGU,74, San Francisco, CA, American Geophysical Union, 431 p.
Protti, M., Guendel, F. and McNally, K., 1995, Correlation between the age of the subducting Cocos Plate and the geometry of the Wadati-Benioff zone under Nicaragua and Costa Rica: Geologic and tectonic development of the Caribbean Plate boundary in southern Central America (GSA Special Paper), 295, 309–326.
Schneider, W.A., 1978, Integral formulation of migration in two and three dimensions, Geophysics 43: 49–76.
Scholz, C.H. and Small, C., 1997, The effect of seamount subduction on seismic coupling, Geology 25: 487–490.
Sen, M.K., Frazer, L.N., Mallick, S. and Chapman, N.R., 1988, Analysis of multipath sound propagation in the ocean near 49 N, 128 W, J. Acoust. Soc. Am. 83: 588–597.
Shipley, T.H., McIntosh, K.D., Silver, E.A. and Stoffa, P.L., 1992, Three-dimensional seismic imaging of the Costa Rica accretionary prism: Structural diversity in a small volume of the lower slope, J. Geophys. Res. 97: 4439–4459.
Shipley, T.H., Moore, G.F., Bangs, N.L., Moore, J.C. and Stoffa, P.L., 1994, Seismically inferred dilatancy distribution, northern Barbados Ridge décollement: implications for fluid migration and fault strength, Geology 22: 411–414.
Sonneland, L., Berg, L.E., Eidsvig, P., Haugen, A., Fotland, B. and Vestby, J., 1986, 2D deghosting using vertical receiver arrays, 56th Ann. Internat. SEG Mtg., Expanded Abstracts, 516–519.
Stavenhagen, A.U., Flueh, E.R., Ranero, C., McIntosh, K.D., Shipley, T., Leandro, G., Schulze, A., and Danobeitia, J.J., 1998, Seismic wide-angle investigations in Costa Rica-A crustal velocity model from the Pacific to the Caribbean coast, Zent. Geol. Paleont. H.3–6 393–408.
Stavenhagen, A.U., 1998, Refraktionsseismische Untersuchungen on-und offshore Costa Rica, Ph. D. thesis, Christian-Albrechts Universität zu Kiel, Kiel, Germany.
Stoffa, P.L., (ed.), 1989, Tau-p, A plane wave approach to the analysis of seismic data, Kluwer Academic Publishers, Dordrecht, 176 p.
Tichelaar, B. and Ruff, L., 1993, Depth of seismic coupling along subduction zones, J. Geophys. Res. 98: 2017–2037.
Um, J. and Thurber, C., 1978, A fast algorithm for two-point seismic ray tracing, Bull. Seis. Soc. Am. 77: 972–986.
Vidale, J.E., 1990, Finite-difference calculation of travel times, Geophysics 56: 521–526.
von Huene, R., Bialas, J., Flueh, E., Cropp, B., Csernok, T., Fabel, E., Hoffmann, J., Emeis, K., Holler, P., Jeschke, G., Leandro, M.C., Perez, F.I., Chavarria, S.J., Florez, H.A., Escobedo, Z., Leon, R. and Barrios, L.O., 1995, Morphotectonics of the Pacific convergent margin of Costa Rica, in Mann, P., ed., Geologic and tectonic development of the Caribbean Plate boundary in southern Central America, Special Paper – Geological Society of America, 295, Boulder, CO, Geological Society of America (GSA), 291–307.
Wang, B., 1993, Improvement of seismic travel-time inversion methods and application to observed data, Ph.D. Dissertation thesis, Purdue University.
Westbrook, G. K. and Smith, M. J., 1983, Long decollements and mud volcanoes: evidence from the Barbados Ridge Complex for the role of high pore-fluid pressure in the development of an accretionary complex, Geology 11: 279–283.
Ye, S., Bialas, J., Flueh, A., Stavenhagen, A. and von Huene, R., 1996, Crustal structure of the Middle American Trench off Costa Rica from wide-angle seismic data, Tectonics 15: 1006–1021.
Zelt, B.C., Talwani, M. and Zelt, C.A., 1998, Prestack depth migration of dense wide-angle seismic data (Deep seismic pro-filing of the continents; I, General results and new methods), Tectonophysics 286: 193–208.
Zelt, C.A., 1994, 3-D velocity structure from simultaneous traveltime inversion of in-line seismic data along intersecting profiles, Geophys. J. Int. 118: 795–801.
Zelt, C.A. and Smith, R.B., 1992, Seismic traveltime inversion for 2-D crustal velocity structure, Geophys. J. Int. 108: 16–34.
Zhao, D., Christensen, D. and Pulpan, H., 1995, Tomographic imaging of the Alaska subduction zone, J. Geophys. Res. 100: 6487–6504
Author information
Authors and Affiliations
Rights and permissions
About this article
Cite this article
McIntosh, K., Akbar, F., Calderon, C. et al. Large aperture seismic imaging at a convergent margin: Techniques and results from the Costa Rica seismogenic zone. Marine Geophysical Researches 21, 451–474 (2000). https://doi.org/10.1023/A:1026597927732
Issue Date:
DOI: https://doi.org/10.1023/A:1026597927732