Drilling-induced and logging-related features illustrated from IODP–ICDP Expedition 364 downhole logs and borehole imaging tools
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Published:2018-10-22
Issue:
Volume:24
Page:1-13
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ISSN:1816-3459
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Container-title:Scientific Drilling
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language:en
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Short-container-title:Sci. Dril.
Author:
Lofi JohannaORCID, Smith David, Delahunty Chris, Le Ber Erwan, Brun Laurent, Henry Gilles, Paris Jehanne, Tikoo Sonia, Zylberman William, Pezard Philippe A., Célérier Bernard, Schmitt Douglas R., Nixon Chris,
Abstract
Abstract. Expedition 364 was a joint IODP and ICDP mission-specific platform (MSP) expedition to explore the Chicxulub impact crater buried below the surface of the Yucatán continental shelf seafloor. In April and May 2016, this expedition drilled a single borehole at Site M0077 into the crater's peak ring. Excellent quality cores were recovered from ∼505 to ∼1335 m below seafloor (m b.s.f.), and high-resolution open hole logs were acquired between the surface and total drill depth. Downhole logs are used to image the borehole wall, measure the physical properties of rocks that surround the borehole, and assess borehole quality during drilling and coring operations. When making geological interpretations of downhole logs, it is essential to be able to distinguish between features that are geological and those that are operation-related. During Expedition 364 some drilling-induced and logging-related features were observed and include the following: effects caused by the presence of casing and metal debris in the hole, logging-tool eccentering, drilling-induced corkscrew shape of the hole, possible re-magnetization of low-coercivity grains within sedimentary rocks, markings on the borehole wall, and drilling-induced changes in the borehole diameter and trajectory.
Publisher
Copernicus GmbH
Subject
Mechanical Engineering,Energy Engineering and Power Technology
Reference27 articles.
1. Anderson, R. N. and Zoback, M. D.: The implications of fracture and void distribution from bore-hole televiewer imagery for the seismic velocity of the upper oceanic crust at Deep Sea Drilling Project Holes 501 and 504B (Costa Rica Rift), Init. Rep. DSDP, 69, 255–270, 1983. 2. Cheung, P. S.: Microresistivity and ultrasonic imagers: tool operations and processing principles with reference to commonly encountered image artefacts, in: Borehole Imaging: applications and case histories, edited by: Lovell, M. A., Williamson, G., and Harvey, P. K., Geol. Soc. Lond., Special Publications, 159, 1, 45–57, 1999. 3. Christeson, G. L., Gulick S. P., Morgan, J. V., Gebhardt, C., Kring, D. A., Le Ber, E., Lofi, J., Nixon, C., Poelchau, M., Rae, A. S. P., Rebolledo-Vieyra, M., Riller, U., Schmitt, D. R., Wittmann, A., Bralower, T. J., Chenot, E., Claeys, P., Cockell, C. S., Coolen, M. J. L., Ferrière, L., Green, S., Goto, K., Jones, H., Lowery, C. M., Mellett, C., Ocampo-Torres, R., Perez-Cruz, L., Pickersgill, A. E., Rasmussen, C., Sato, H., Smit, J., Tikoo- Schantz, S. M., Tomioka, N., Urrutia-Fucugauchi, J., Whalen, M. T., Xiao, L., Yamaguchi, K. E., and Zylberman, W.: Extraordinary Rocks from the Peak Ring of the Chicxulub Impact Crater: Physical Property Measurements from IODP/ICDP Expedition 364, EPSL, 495, 1–11, 2018. 4. Fuller, M., Hastedt, M., and Herr, B.: Coring-induced magnetization of recovered sediment, Proc. ODP, Sci. Res., 145, 455–468, 1998. 5. Ekstrom, M. E., Dahan, C., Chen, M.-Y., Lloyd, P., and Rossi, D. J.: Formation imaging with microelectrical scanning arrays, The Log Analyst, 28, 294–306, 1987.
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