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Quantitative compaction trends of Miocene to Holocene carbonates off the west coast of Australia

Authors :
Stephen J. Gallagher
Takeshige Ishiwa
Lars Reuning
Eun Lee
Hideko Takayanagi
Wolfgang Knierzinger
Michelle A. Kominz
Michael Wagreich
Source :
Australian Journal of Earth Sciences. 68:1149-1161
Publication Year :
2021
Publisher :
Informa UK Limited, 2021.

Abstract

In this paper, we describe porosity variations in Miocene to Holocene carbonates off the west coast of Australia and assess their compaction trends. The porosity values were measured using discrete samples of Sites U1459–U1464 obtained by the International Ocean Discovery Program Expedition 356. The carbonate deposits have been influenced by a range of textures and diagenetic conditions throughout a nearly continuous sequence of geological ages from the Miocene to Holocene and at core depths from 0 to 1100 m below the seafloor. The collected samples were mostly grainstone, packstone, wackestone and mudstone textures. Dolostones and dolomitic carbonates were described at the Miocene intervals. Compaction trends were estimated exponentially and linearly based on cored sites, carbonate textures and dominant mineralogies (dolomite, calcite/aragonite). At all six sites, porosity distribution and reduction were generally depth-dependent. The porosity converged to about 30% between 750 and 1100 m, which suggests that the carbonates were close to the densest packing by mechanical compaction at a burial depth of ∼750 m. The porosity deviations are associated with textures and dominant mineralogies. Increasing mud content from grainstone to mudstone is a controlling factor for initial porosity and porosity reduction rate. Dolomitisation, dolomitic cementation, aragonite needle-rich mud and non-skeletal grains cause deviations from the depth-dependent compaction trends. Reflux-related cementation generally decreases porosity in Miocene dolomitic intervals. Higher porosity values of the Quaternary wackestone and mudstone at Site U1461 resulted from the presence of aragonite needle-rich mud hosting abundant micropores and from a high sedimentation rate. The occurrence of non-skeletal grains, such as ooids and peloids, as well as occasional meteoric exposure led to porosity inversion, occluding interparticle permeability and the creation of moldic pores.

Details

ISSN :
14400952 and 08120099
Volume :
68
Database :
OpenAIRE
Journal :
Australian Journal of Earth Sciences
Accession number :
edsair.doi...........1383aeb3bfe87ac858c9382d81cde090
Full Text :
https://doi.org/10.1080/08120099.2021.1915867