Utilizing Chemostratigraphic Techniques to Improve Lacustrine Carbonate Reservoir
Characterization
Lepley, Scott1 and Piccoli, Leonardo
1[email protected]
A major challenge facing the understanding of lacustrine carbonates
is the lateral prediction of
reservoir
properties away from the well-bore. Heterogeneities in the South Atlantic Lower Cretaceous lacustrine
carbonates
are difficult to extrapolate laterally given the current limitations on seismic and pre-salt rock data. This in turn affects the ability to construct adequately-defined depositional models and predict
reservoir
presence and quality within a field, impacting optimal well placement. A relatively low-cost inorganic chemostratigraphic-based approach utilizing existing rock material (RSWC & conventional core) can help provide further insight into these complications. Specific geochemical techniques can therefore enhance the understanding of the spatial and temporal distributions of
reservoir
characteristics.
While traditional rock evaluation techniques often provide an adequate analysis of well-bore geology, reservoir
modelling requires a geologically-underpinned dataset in undrilled areas to support its calculations. Certain geochemical procedures can infer larger scale depositional patterns and environments that are driven by primary processes, such as regional changes in base level or chemical conditions. The first approach uses elemental geochemistry (XRF or equivalent) that enables the analysis of over 50 elements and compounds. A second approach uses stable isotope geochemistry (δ13C and δ18O). The third approach uses strontium isotope ratios (87Sr/86Sr). Each technique can be utilized to address specific questions, and are most beneficial when information from one can be corroborated with another. Preliminary results reveal the validity and applicability in lacustrine
carbonates
of the Cretaceous south Atlantic.
Complemented by core descriptions and well log data, these methods can be utilized to add significant value to subsurface products such as depositional models and reservoir
quality distributions. The final
reservoir
model is then expected to be more geologically robust, thereby assisting with well placement planning for future production purposes.
AAPG Search and Discovery Article #90166©2013 AAPG International Conference & Exhibition, Cartagena, Colombia, 8-11 September 2013