Velocity and density of sediments of Eirik Ridge, Labrador Sea: control by porosity and mineralogy

Journal Article A 767-m section of late Neogene (0-8 Ma) terrigenous sediments was cored at Ocean Drilling Program (ODP) Site 646. Continuous downhole geophysical logs, 161 laboratory measurements of core porosity and density, and 63 laboratory measurements of core velocity are used to analyze in de...

Full description

Bibliographic Details
Main Authors: Jarrard, Richard D., Dadey, Kathleen A.; Busch, William H.
Other Authors: College of Mines & Earth Sciences, Geology & Geophysics
Format: Text
Language:English
Published: Ocean Drilling Program 1989
Subjects:
Eirik Ridge
Labrador Sea
Online Access:https://collections.lib.utah.edu/ark:/87278/s6j39b4v
id ftunivutah:oai:collections.lib.utah.edu:ir_uspace/706621
record_format openpolar
spelling ftunivutah:oai:collections.lib.utah.edu:ir_uspace/706621 2023-05-15T17:06:14+02:00 Velocity and density of sediments of Eirik Ridge, Labrador Sea: control by porosity and mineralogy Jarrard, Richard D. Dadey, Kathleen A.; Busch, William H. College of Mines & Earth Sciences Geology & Geophysics 1989 application/pdf 6,727,768 bytes https://collections.lib.utah.edu/ark:/87278/s6j39b4v eng eng Ocean Drilling Program ir-main,11237 https://collections.lib.utah.edu/ark:/87278/s6j39b4v ©Ocean Drilling Program, Reprinted from Jarrard, R. D., Dadey, K. A., & Busch, W. H. (1989). Velocity and density of sediments of Eirik Ridge, Labrador Sea: control by porosity and mineralogy. Scientific Results, ODP. 105, 811-35. Text 1989 ftunivutah 2021-06-03T18:22:43Z Journal Article A 767-m section of late Neogene (0-8 Ma) terrigenous sediments was cored at Ocean Drilling Program (ODP) Site 646. Continuous downhole geophysical logs, 161 laboratory measurements of core porosity and density, and 63 laboratory measurements of core velocity are used to analyze in detail the effects of porosity and mineralogy on the acoustic properties at this site. Porosity (determined from a resistivity log) agrees well with rebound-corrected laboratory measurements. Mineralogical variations (potassium feldspar, quartz plus plagioclase, calcite plus opal, and clay minerals) for the interval 206-737 mbsf were determined by matrix inversion of three logs: bound water, potassium, and uranium/ thorium ratio. These calculated mineralogical variations are similar in major features to mineral abundances from smear slides, but the wide depth spacing of smear slides and their subjective, semiquantitative mineral abundances preclude a detailed comparison. Calculated grain densities from mineralogy are consistent with laboratory measurements. A pseudodensity log from porosity and grain density is similar in character to the rebound-corrected, bulk-density measurements on cores, but about 0.1 g/cm3 lower than core measurements in the interval 340-737 mbsf. We found from our analyses that a strong synergy exists between downhole geophysical logs and core measurements of porosity and density: (1) core recovery is best at shallow depths, and logs are more reliable at greater depths; and (2) agreement between laboratory and log measurements corroborates the different assumptions made when analyzing the two data types. At Site 646, this synergy does not extend to laboratory measurements of velocity; laboratory velocities are lower than in-situ velocities, but higher than expected when rebound is considered. Observed trends of laboratory and log porosity, density, and velocity as a function of depth at Site 646 are in reasonable agreement with empirical trends. In contrast, empirical relationships of velocity to porosity do not agree well with our data. Application of Hookean elastic equations to our data is hampered by the lack of shear wave velocities and the sensitivity of the technique to small errors in porosities. Nevertheless, this theoretical approach yields a pseudovelocity log that agrees remarkably well with observed in-situ log velocities. Text Labrador Sea The University of Utah: J. Willard Marriott Digital Library Eirik Ridge ENVELOPE(-44.500,-44.500,58.500,58.500)
institution Open Polar
collection The University of Utah: J. Willard Marriott Digital Library
op_collection_id ftunivutah
language English
description Journal Article A 767-m section of late Neogene (0-8 Ma) terrigenous sediments was cored at Ocean Drilling Program (ODP) Site 646. Continuous downhole geophysical logs, 161 laboratory measurements of core porosity and density, and 63 laboratory measurements of core velocity are used to analyze in detail the effects of porosity and mineralogy on the acoustic properties at this site. Porosity (determined from a resistivity log) agrees well with rebound-corrected laboratory measurements. Mineralogical variations (potassium feldspar, quartz plus plagioclase, calcite plus opal, and clay minerals) for the interval 206-737 mbsf were determined by matrix inversion of three logs: bound water, potassium, and uranium/ thorium ratio. These calculated mineralogical variations are similar in major features to mineral abundances from smear slides, but the wide depth spacing of smear slides and their subjective, semiquantitative mineral abundances preclude a detailed comparison. Calculated grain densities from mineralogy are consistent with laboratory measurements. A pseudodensity log from porosity and grain density is similar in character to the rebound-corrected, bulk-density measurements on cores, but about 0.1 g/cm3 lower than core measurements in the interval 340-737 mbsf. We found from our analyses that a strong synergy exists between downhole geophysical logs and core measurements of porosity and density: (1) core recovery is best at shallow depths, and logs are more reliable at greater depths; and (2) agreement between laboratory and log measurements corroborates the different assumptions made when analyzing the two data types. At Site 646, this synergy does not extend to laboratory measurements of velocity; laboratory velocities are lower than in-situ velocities, but higher than expected when rebound is considered. Observed trends of laboratory and log porosity, density, and velocity as a function of depth at Site 646 are in reasonable agreement with empirical trends. In contrast, empirical relationships of velocity to porosity do not agree well with our data. Application of Hookean elastic equations to our data is hampered by the lack of shear wave velocities and the sensitivity of the technique to small errors in porosities. Nevertheless, this theoretical approach yields a pseudovelocity log that agrees remarkably well with observed in-situ log velocities.
author2 College of Mines & Earth Sciences
Geology & Geophysics
format Text
author Jarrard, Richard D.
Dadey, Kathleen A.; Busch, William H.
spellingShingle Jarrard, Richard D.
Dadey, Kathleen A.; Busch, William H.
Velocity and density of sediments of Eirik Ridge, Labrador Sea: control by porosity and mineralogy
author_facet Jarrard, Richard D.
Dadey, Kathleen A.; Busch, William H.
author_sort Jarrard, Richard D.
title Velocity and density of sediments of Eirik Ridge, Labrador Sea: control by porosity and mineralogy
title_short Velocity and density of sediments of Eirik Ridge, Labrador Sea: control by porosity and mineralogy
title_full Velocity and density of sediments of Eirik Ridge, Labrador Sea: control by porosity and mineralogy
title_fullStr Velocity and density of sediments of Eirik Ridge, Labrador Sea: control by porosity and mineralogy
title_full_unstemmed Velocity and density of sediments of Eirik Ridge, Labrador Sea: control by porosity and mineralogy
title_sort velocity and density of sediments of eirik ridge, labrador sea: control by porosity and mineralogy
publisher Ocean Drilling Program
publishDate 1989
url https://collections.lib.utah.edu/ark:/87278/s6j39b4v
long_lat ENVELOPE(-44.500,-44.500,58.500,58.500)
geographic Eirik Ridge
geographic_facet Eirik Ridge
genre Labrador Sea
genre_facet Labrador Sea
op_relation ir-main,11237
https://collections.lib.utah.edu/ark:/87278/s6j39b4v
op_rights ©Ocean Drilling Program, Reprinted from Jarrard, R. D., Dadey, K. A., & Busch, W. H. (1989). Velocity and density of sediments of Eirik Ridge, Labrador Sea: control by porosity and mineralogy. Scientific Results, ODP. 105, 811-35.
_version_ 1766061277260546048

Similar Items