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by Wolfgang van Berk, Yunjiao Fu, and Hans-Martin Schulz

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Presentation on theme: "by Wolfgang van Berk, Yunjiao Fu, and Hans-Martin Schulz"— Presentation transcript:

1 by Wolfgang van Berk, Yunjiao Fu, and Hans-Martin Schulz
Creation of pre-oil-charging porosity by migration of source-rock-derived corrosive fluids through carbonate reservoirs: one-dimensional reactive mass transport modelling by Wolfgang van Berk, Yunjiao Fu, and Hans-Martin Schulz Petroleum Geoscience Volume 21(1):35-42 February 2, 2015 © 2015 EAGE/Geological Society of London

2 Batch and one-dimensional reactive mass transport modelling scenarios.
Wolfgang van Berk et al. Petroleum Geoscience 2015;21:35-42 © 2015 EAGE/Geological Society of London

3 Modelling results from batch modelling scenarios ‘5’, ‘6’ and ‘7’.
Wolfgang van Berk et al. Petroleum Geoscience 2015;21:35-42 © 2015 EAGE/Geological Society of London

4 Modelling results from batch modelling scenario ‘1’.
Modelling results from batch modelling scenario ‘1’. ACF generation within siliciclastic source rocks: pH and mineral content depend on the continuous addition of kerogen maturation products (KMP). KMP addition of more than 0.5 mol leads to the complete consumption of the initial acid-buffering capacity by calcite, anorthite, albite and K-feldspar within the source rock (0.01 mol each; black bar). Wolfgang van Berk et al. Petroleum Geoscience 2015;21:35-42 © 2015 EAGE/Geological Society of London

5 Solubility constants for calcite , in mol kgw–1) calculated for various pressure and temperature conditions using the Phreeqc Interactive computer code in combination with its phreeqc.dat database (Parkhurst & Appelo 2013). Solubility constants for calcite , in mol kgw–1) calculated for various pressure and temperature conditions using the Phreeqc Interactive computer code in combination with its phreeqc.dat database (Parkhurst & Appelo 2013). Circles indicate the P–T conditions. Wolfgang van Berk et al. Petroleum Geoscience 2015;21:35-42 © 2015 EAGE/Geological Society of London

6 Modelling results from batch modelling scenarios ‘8’ and ‘9’.
Modelling results from batch modelling scenarios ‘8’ and ‘9’. Amount of dissolved calcite, dissolved CO2(g) and pH; equilibration with calcite and pCO2(g) of 10 atm at 305 atm/85 °C v. 205 atm/55 °C Wolfgang van Berk et al. Petroleum Geoscience 2015;21:35-42 © 2015 EAGE/Geological Society of London

7 Modelling results from 1DRT modelling scenario ‘11’.
Modelling results from 1DRT modelling scenario ‘11’. Amount of dissolved calcite (g cell–1: first number next to the circles) and corresponding pH values along the migration path of ACF through the carbonate reservoir rock column. ‘Number of pore volumes displaced’: n = 1000. For the corresponding ACF influx composition see Table 2 (scenario ‘6’). Circles indicate the P–T conditions. Wolfgang van Berk et al. Petroleum Geoscience 2015;21:35-42 © 2015 EAGE/Geological Society of London

8 Modelling results from 1DRT modelling scenarios (a) ‘10’, (b) ‘11’ and (c) ‘12’.
Modelling results from 1DRT modelling scenarios (a) ‘10’, (b) ‘11’ and (c) ‘12’. Scenario ‘11’ considers the average intensity of ACF generation by the release of 1.0 mol KMP (0.1 and 10.0 mol in scenarios ‘10’ and ‘12’, respectively). Amount of dissolved calcite (g cell–1) along the migration path of ACF through the carbonate reservoir rock column for different ‘numbers of pore volumes displaced (n)’: green bars, n = 10; light-blue bars, n = 100: dark-blue bars: n = 1000. Wolfgang van Berk et al. Petroleum Geoscience 2015;21:35-42 © 2015 EAGE/Geological Society of London

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