Invited Papers from the 12th International Conference on Theoretical and Computational Acoustics (ICTCA 2015); Guest Editor: Yuefeng SunNo Access

Dolomitization Associated with Sea Level and Ocean Current Circulation in the Southern Marion Platform, Offshore Ne Australia

Tingting Zhang

Department of Geology and Geophysics, Texas A&M University, College Station, Texas 77843, USA

E-mail Address: tzhang@geo.tamu.edu

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and

Yuefeng Sun

Department of Geology and Geophysics, Texas A&M University, College Station, Texas 77843, USA

E-mail Address: sun@geo.tamu.edu

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https://doi.org/10.1142/S0218396X15400056Cited by:0 (Source: Crossref)

Abstract

On the Southern Marion carbonate platform, dolomitization is triggered by the circulation of normal or slightly modified seawater and is related to changes in sedimentation rate and sea level change. Dolomitization further modifies formation permeability and fluid flow patterns. Dolostone/calcareous dolostone with large vuggy or moldic porosity is formed by fabric-preserving dissolution and recrystallization, which increases the pore space and facilitates the fluid flow effectively, with permeability ranging from 1mD to 10,000mD. The frame flexibility factor ( $γ$ $γ$ ) is a rock physics parameter which is a proxy of pore structure. We find that at given porosity dolostone with larger pores, higher permeability and higher sonic velocity usually has lower values of frame flexibility factor than limestone. After strong compaction and cementation, the limestone frame occludes fluid flow, prevents dolomitization and has permeability as low as 0.02mD.

Acoustic impedance inversion confirms that the asymmetric geometry of the Southern Marion platform is shaped by the oceanographic currents, which are caused by the southward-flowing East Australian Current. Three layers of dolostone with large pores in the upper platform reveal strong fluid flow within the carbonate platform, leading to dolomitization and dissolution. These three strongly dolomitized zones follow the platform topography, indicating that the diagenetic fluid flow is driven by oceanographic currents. Three large-pore-formation dolomitization events match well with three highstands of sea level events, illustrating that the highstand of sea level induces the formation of dolomitization zones with large pores. This study demonstrates the positive feedback loop of dolomitization and ocean current circulation, as well as the relationship between dolomitization and sea level change, which could be applicable for better understanding subsurface fluid-rock interactions and dolomitization pore systems in other carbonate environments.

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References

1. A. R. Isern, F. S. Anselmetti and P. Blum, A neogene carbonate platform, slope, and shelf edifice shaped by sea level and ocean currents, Marion Plateau (northeast Australia), in Seismic Imaging of Carbonate Reservoirs and Systems: AAPG Memoir 81 (AAPG, 2004), pp. 291–307. Google Scholar
2. S. N. Ehrenberg, G. P. Eberli and G. L. Bracco Gartner, Data report: Porosity and permeability of Miocene, Ocean Drill. Program, Sci. Results 194 (2004) 1–217, Available at: http://www.odp.tamu.edu/publications/194_SR/VOLUME/CHAPTERS/007.PDF. Google Scholar
3. S. N. Ehrenberg, G. P. Eberli and G. Baechle, Porosity-permeability relationships in Miocene carbonate platforms and slopes seaward of the Great Barrier Reef, Australia (ODP Leg 194, Marion Plateau), Sedimentol. 53 (2006a) 1289–1318. Crossref, Web of Science, Google Scholar
4. G. A. R. Conesa, E. Favre, P. M’́unch, H. Dalmasso and C. Chaix, Biosedimentary and paleoenvironmental evolution of the Southern Marion platform from the middle to late Miocene (northeast Australia, ODP Leg 194, Sites 1196 and 1199), Proc. Ocean Drill. Program 194 (2005) 1–38, Available at: http://www-odp.tamu.edu/publications/194_SR/VOLUME/CHAPTERS/005.PDF. Google Scholar
5. S. N. Ehrenberg, J. M. McArthur and M. F. Thirlwall, Growth, demise, and dolomitization of Miocene carbonate platforms on the Marion Plateau, offshore NE Australia, J. Sediment. Res. 76 (2006b) 91–116. Crossref, Web of Science, Google Scholar
6. R. J. Weger, G. P. Eberli, G. T. Baechle, J. L. Massaferro and Y.-F. Sun, Quantification of pore structure and its effect on sonic velocity and permeability in carbonates, AAPG Bulletin 93(10) (2009) 1297–1317. Crossref, Web of Science, Google Scholar
7. Y. F. Sun, Upscaling of a proxy parameter for pore structure in sedimentary rocks: Presented at SEG/San Antonio 2007 Annual Meeting (2007). Google Scholar
8. Y. F. Sun, Pore structure effects on velocity-porosity relationship in carbonates, Shell International Exploration and Production B.V. (The Hague, the Netherlands, 2001), EP 2001-5092. Google Scholar
9. Y. F. Sun, Effects of pore structure on elastic wave propagation in rocks, AVO modeling, J. Geophys. Eng. 1 (2004) 268–276. Crossref, Web of Science, Google Scholar
10. H. Adesokan and Y. F. Sun, Rock-physics-based Estimation of Critical Volume of Shale and Its Effect on Seismic and Petrophysical Properties: A North-Sea Example, in 2010 SEG Annual Meeting (Denver, Colorado, US, October 17–22, 2010). Google Scholar
11. Q. Dou, Y. F. Sun and C. Sullivan, Rock-physics-based pore type characterization and its application in carbonate reservoir permeability heterogeneity evaluation, Upper San Andres reservoir, Permian Basin, west Texas, J. Appl. Geophys. 74 (2011a) 8–18. Crossref, Web of Science, Google Scholar
12. Q. Dou, Y. F. Sun, H. Zhang, T. Zhang, T. Guo and X. Cai, Rock-physics-based Permeability Heterogeneity and Fluid Evaluation of an Ultra-Deep Low-Porosity Carbonate Reservoir, Sichuan Basin, China: I. Petrophysical Study, in AAPG 2011 Annual Convention & Exhibition (Houston, US, April 10–13, 2011b). Google Scholar
13. Y. F. Sun, H. Zhang, Q. Dou, T. Zhang and T. Guo, Geological and GeophysicalCharacteristics of the Ultra-Deep High-Porosity Carbonate Gas Reservoir, Puguang Gas Field, Sichuan Basin, China: I. Petrophysical Study, in AAPG 2011 Annual Convention & Exhibition (Houston, US, April 10–13, 2011). Google Scholar
14. H. Zhang, Y. F. Sun, Q. Dou and T. Zhang, Preliminary application of the frame flexibility factor in Puguang gas field, Oil and Gas Geol. 33 (2012) 877–882. Google Scholar
15. T. Zhang, Q. Dou, Y. F. Sun and H. Zhang, Improving porosity-velocity relations using carbonate pore types, in SEG 2012 Annual Meeting (Las Vegas, US, November 4–9, 2012). Google Scholar
16. D. H. Han and M. L. Batzel, Gassmanns equation and fluid-saturation effects on seismic velocities, Geophysics 69(2) (2004) 398–405. Crossref, Web of Science, Google Scholar
17. F. S. Anselmetti, A. R. Isern, S. N. Ehrenberg and G. P. Eberli, Proceeding of the Ocean Drilling Program, Preliminary Report, Ocean Drilling Program (Texas A&M University, College Station, Texas, Ocean Drilling Program, 2001), p. 194. Google Scholar
18. Leg 194 Shipboard Scientific Party, ODP Leg 194: Marion Plateau Carbonate Platform, NE Australia (Downhole Logging Summary, 2001), Available at: http://www-odp.tamu.edu/publications/prelim/194_prel/194PREL.PDF. Google Scholar