Downhole seismic logging for high‐resolution reflection surveying in unconsolidated overburden

Downhole seismic velocity logging techniques have been developed and applied in support of high‐resolution reflection seismic surveys. For shallow high‐resolution reflection surveying within unconsolidated overburden, velocity‐depth control can sometimes be difficult to achieve; as well, unambiguous...

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Published in:	GEOPHYSICS
Main Authors:	Hunter, J.A., Pullan, S.E., Burns, R.A., Good, R.L., Harris, J.B., Pugin, André, Skvortsov, A., Goriainov, N.N.
Format:	Article in Journal/Newspaper
Language:	English
Published:	1998
Subjects:	info:eu-repo/classification/ddc/550 Ice permafrost
Online Access:	https://archive-ouverte.unige.ch/unige:156570

id	ftunivgeneve:oai:unige.ch:unige:156570
record_format	openpolar
spelling	ftunivgeneve:oai:unige.ch:unige:156570 2023-05-15T16:37:55+02:00 Downhole seismic logging for high‐resolution reflection surveying in unconsolidated overburden Hunter, J.A. Pullan, S.E. Burns, R.A. Good, R.L. Harris, J.B. Pugin, André Skvortsov, A. Goriainov, N.N. 1998 https://archive-ouverte.unige.ch/unige:156570 eng eng info:eu-repo/semantics/altIdentifier/doi/10.1190/1.1444439 unige:156570 https://archive-ouverte.unige.ch/unige:156570 info:eu-repo/semantics/restrictedAccess ISSN: 0016-8033 Geophysics, Vol. 63, No 4 (1998) pp. 1371-1384 info:eu-repo/classification/ddc/550 Text info:eu-repo/semantics/article Article scientifique info:eu-repo/semantics/publishedVersion 1998 ftunivgeneve https://doi.org/10.1190/1.1444439 2022-02-08T22:31:28Z Downhole seismic velocity logging techniques have been developed and applied in support of high‐resolution reflection seismic surveys. For shallow high‐resolution reflection surveying within unconsolidated overburden, velocity‐depth control can sometimes be difficult to achieve; as well, unambiguous correlation of reflections with overburden stratigraphy is often problematic. Data obtained from downhole seismic logging can provide accurate velocity‐depth functions and directly correlate seismic reflections to depth. The methodologies described in this paper are designed for slimhole applications in plastic‐cased boreholes (minimum ID of 50 mm) and with source and detector arrays that yield similar frequency ranges and vertical depth resolutions as the surface reflection surveys. Compressional- (P-) wave logging uses a multichannel hydrophone array with 0.5-m detector spacings in a fluid‐filled borehole and a high‐frequency, in‐hole shotgun source at the surface. Overlapping array positions downhole results in redundant first‐arrival data (picked using interactive computer techniques), which can be processed to provide accurate interval velocities. The data also can be displayed as a record suite, showing reflections and directly correlating reflection events with depths. Example applications include identification of gas zones, lithological boundaries within unconsolidated sediments, and the overburden‐bedrock interface. Shear- (S-) wave logging uses a slimhole, well‐locked, three‐component (3-C) geophone pod and a horizontally polarized, hammer‐and‐loaded‐plate source at ground surface. The pod is moved in successive 0.5- or 1-m intervals downhole with no redundancy of overlapping data as in the P-wave method. First‐arrival data can be obtained by picking the crossover onset of polarized energy or by closely examining particle‐motion plots using all three components of motion. In unconsolidated sediments, shear‐wave velocity contrasts can be associated with changes in material density or dynamic shear modulus, which in turn can be related to consolidation. Example applications include identification of a lithological boundary for earthquake hazard applications and mapping massive ice within permafrost materials. Article in Journal/Newspaper Ice permafrost Université de Genève: Archive ouverte UNIGE GEOPHYSICS 63 4 1371 1384
institution	Open Polar
collection	Université de Genève: Archive ouverte UNIGE
op_collection_id	ftunivgeneve
language	English
topic	info:eu-repo/classification/ddc/550
spellingShingle	info:eu-repo/classification/ddc/550 Hunter, J.A. Pullan, S.E. Burns, R.A. Good, R.L. Harris, J.B. Pugin, André Skvortsov, A. Goriainov, N.N. Downhole seismic logging for high‐resolution reflection surveying in unconsolidated overburden
topic_facet	info:eu-repo/classification/ddc/550
description	Downhole seismic velocity logging techniques have been developed and applied in support of high‐resolution reflection seismic surveys. For shallow high‐resolution reflection surveying within unconsolidated overburden, velocity‐depth control can sometimes be difficult to achieve; as well, unambiguous correlation of reflections with overburden stratigraphy is often problematic. Data obtained from downhole seismic logging can provide accurate velocity‐depth functions and directly correlate seismic reflections to depth. The methodologies described in this paper are designed for slimhole applications in plastic‐cased boreholes (minimum ID of 50 mm) and with source and detector arrays that yield similar frequency ranges and vertical depth resolutions as the surface reflection surveys. Compressional- (P-) wave logging uses a multichannel hydrophone array with 0.5-m detector spacings in a fluid‐filled borehole and a high‐frequency, in‐hole shotgun source at the surface. Overlapping array positions downhole results in redundant first‐arrival data (picked using interactive computer techniques), which can be processed to provide accurate interval velocities. The data also can be displayed as a record suite, showing reflections and directly correlating reflection events with depths. Example applications include identification of gas zones, lithological boundaries within unconsolidated sediments, and the overburden‐bedrock interface. Shear- (S-) wave logging uses a slimhole, well‐locked, three‐component (3-C) geophone pod and a horizontally polarized, hammer‐and‐loaded‐plate source at ground surface. The pod is moved in successive 0.5- or 1-m intervals downhole with no redundancy of overlapping data as in the P-wave method. First‐arrival data can be obtained by picking the crossover onset of polarized energy or by closely examining particle‐motion plots using all three components of motion. In unconsolidated sediments, shear‐wave velocity contrasts can be associated with changes in material density or dynamic shear modulus, which in turn can be related to consolidation. Example applications include identification of a lithological boundary for earthquake hazard applications and mapping massive ice within permafrost materials.
format	Article in Journal/Newspaper
author	Hunter, J.A. Pullan, S.E. Burns, R.A. Good, R.L. Harris, J.B. Pugin, André Skvortsov, A. Goriainov, N.N.
author_facet	Hunter, J.A. Pullan, S.E. Burns, R.A. Good, R.L. Harris, J.B. Pugin, André Skvortsov, A. Goriainov, N.N.
author_sort	Hunter, J.A.
title	Downhole seismic logging for high‐resolution reflection surveying in unconsolidated overburden
title_short	Downhole seismic logging for high‐resolution reflection surveying in unconsolidated overburden
title_full	Downhole seismic logging for high‐resolution reflection surveying in unconsolidated overburden
title_fullStr	Downhole seismic logging for high‐resolution reflection surveying in unconsolidated overburden
title_full_unstemmed	Downhole seismic logging for high‐resolution reflection surveying in unconsolidated overburden
title_sort	downhole seismic logging for high‐resolution reflection surveying in unconsolidated overburden
publishDate	1998
url	https://archive-ouverte.unige.ch/unige:156570
genre	Ice permafrost
genre_facet	Ice permafrost
op_source	ISSN: 0016-8033 Geophysics, Vol. 63, No 4 (1998) pp. 1371-1384
op_relation	info:eu-repo/semantics/altIdentifier/doi/10.1190/1.1444439 unige:156570 https://archive-ouverte.unige.ch/unige:156570
op_rights	info:eu-repo/semantics/restrictedAccess
op_doi	https://doi.org/10.1190/1.1444439
container_title	GEOPHYSICS
container_volume	63
container_issue	4
container_start_page	1371
op_container_end_page	1384
_version_	1766028225897562112

Downhole seismic logging for high‐resolution reflection surveying in unconsolidated overburden

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