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Chapter 9: Subsidence and Thermal History

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Presentation on theme: "Chapter 9: Subsidence and Thermal History"— Presentation transcript:

1 Chapter 9: Subsidence and Thermal History
This presentation contains illustrations from Allen and Allen (2005)

2 Geohistory Analysis Quantitative analysis that produces subsidence of various geological boundaries and rates of sediment accumulation through time. Coined by Van Hinte (1973). Backstripping involves additional incorporation of isostatic (local, flexural, 1-D, 2-Dor 3-D) effects of sediment unloading.

3 Subsidence History and Thermal History
time present past Layer 3 Layer 2 “Tectonic” subsidence” Layer 1 depth basement

4 Backstripping (Watts and Ryan, 1976)
Tectonic subsidence is what remains after the effects of sea-level and sediments are removed. …. It is the background subsidence caused by stretching and thermal cooling of the lithosphere.

5 Backstripping

6 Backstripping For original matlab program from Allen’s book:
see the following link to a matlab program

7 Subsidence History and Thermal History
time present past Layer 3 Layer 2 “Tectonic” subsidence” Layer 1 depth Thermal window

8 Subsidence in the forward sense
Sea-level

9 Subsidence in the forward sense
Sea-level

10 Subsidence in the forward sense
Sea-level

11 Subsidence in the forward sense

12 Subsidence in the forward sense

13 Subsidence in the forward sense

14 Subsidence in the forward sense
We need to know: Sea-level (assumed constant in the example) Original sediment thickness and hence water-depth (known at all times) Type of isostatic behavior does the crust exhibit when loaded (flexural, or local/Airy)

15 Subsidence in the reverse sense
Sea-level (never constant in the past) Original sediment thickness ( we don’t know??) We DO know current sediment thickness Water-depths ( never constant)

16 Subsidence in the reverse sense

17 Subsidence in the reverse sense
Porosity: The “new”decompacted thickness must conform to a pre-defined porosity-depth relation. This calculation is achieved by trial and error.

18 Subsidence in the reverse sense
Paleo-water depth: From biostratigraphic assemblages Sea-level estimations: Long-term changes are accepted. Flexural Model: Various Te values can be used.

19 Flexural backstripping

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