In sedimentology, compaction is the process by which a sediment progressively loses its porosity due to the effects of pressure from loading. This forms part of the process of lithification. When a layer of sediment is originally deposited, it contains an open framework of particles with the pore space being usually filled with water. As more sediment is deposited above the layer, the effect of the increased loading is to increase the particle-to-particle stresses resulting in porosity reduction primarily through a more efficient packing of the particles and to a lesser extent through elastic compression and pressure solution. The initial porosity of a sediment depends on its lithology. Mudstones start with porosities of >60%, sandstones typically ~40% and carbonates sometimes as high as 70%. Results from hydrocarbon exploration wells show clear porosity reduction trends with depth.[1] Compaction trend estimation and decompaction process are useful for analyzing numerical basin evolution (e.g., subsidence) and evaluating hydrocarbon reservoirs and geological storages.[2]
In sediments compacted under self-weight, especially in sedimentary basins, the porosity profiles often show an exponential decrease, called Athy's law as first shown by Athy in 1930. A mathematical analytical solution was obtained by Fowler and Yang[3] to show the theoretical basis for Athy's law. This process can be easily observed in experiments and used as a good approximation to many real data.[4]
Differential compaction
If there is a variation in thickness and compactability of a sequence, loading by later deposits will give rise to spatially varying amounts of compaction. This form of compaction is a function of the lithology of the base sediment. Both the thickness and structure of the later sequence will be controlled by the underlying geology in the absence of any active tectonics. Buried tilted fault blocks in a rift basin often produce large anticlinal closures in the post-rift section that may form traps for hydrocarbons e.g. the Daqing Field, the largest oil field in the People's Republic of China, in the Songliao Basin.[5]
References
- ^ Sclater, J.G. & Christie, P.A.F. 1980. Continental stretching: an explanation of the post-mid-Cretaceous subsidence of the Central North Sea Basin. Journal of Geophysical Research, 85, 3711–3739.
- ^ Lee, E.Y., Novotny, J., Wagreich, M. (2020) Compaction trend estimation and applications to sedimentary basin reconstruction (BasinVis 2.0). Applied Computing and Geosciences, 5, 100015. https://doi.org/10.1016/j.acags.2019.100015
- ^ A. C. Fowler and X. S. Yang, Fast and slow compaction in sedimentary basins, SIAM Journal on Applied Mathematics, 59, 365-385 (1998.)
- ^ D. B. Bahr, E. W. Hutton, J. P. Syvitski, L. F. Pratson, Exponential approximations to compacted sediment porosity profiles, Computers & Geosciences, 27, 691-700 (2001).
- ^ http://energy.cr.usgs.gov/WEcont/regions/reg3/P3/tps/AU/au314412.pdf%7C[permanent dead link] USGS report on the Songliao Basin
Geologic principles and processes | ||
|---|---|---|
| Stratigraphic principles |  | |
| Petrologic principles | ||
| Geomorphologic processes | ||
| Sediment transport | ||
 | This sedimentology article is a stub. You can help Wikipedia by expanding it. |
This page was last edited on 26 July 2023, at 18:08