Changes

[[Distributary mouth bar]]s and channel deposits ([[:file:lithofacies-and-environmental-analysis-of-clastic-depositional-systems_fig3.png|Figure 3h]]) comprise the best reservoir quality bodies within a delta system. The general upward-coarsening character of distributary mouth bars tends to produce sandstone bodies that have their greatest [[permeability]] at the top. Conversely, distributary channel sandstone bodies are usually upward-fining and have their greatest permeability at the base.<ref name=pt06r130 /> Preferred orientation of flow may be expected to follow paleochannel trends.

[[Distributary mouth bar]]s and channel deposits ([[:file:lithofacies-and-environmental-analysis-of-clastic-depositional-systems_fig3.png|Figure 3h]]) comprise the best reservoir quality bodies within a delta system. The general upward-coarsening character of distributary mouth bars tends to produce sandstone bodies that have their greatest [[permeability]] at the top. Conversely, distributary channel sandstone bodies are usually upward-fining and have their greatest permeability at the base.<ref name=pt06r130 /> Preferred orientation of flow may be expected to follow paleochannel trends.

Distributary mouth bars typically contain a high percentage of interstratified clay that reduces [[Directional permeability|vertical permeability]]. Hartman and Paynter<ref name=pt06r50>Hartman, J. A., Paynter, D. D., 1979, Drainage anomalies in Gulf Coast Tertiary sandstones: Journal of Petroleum Technology, Oct., p. 1313–1322.</ref> document an example of such behavior from a Gulf Coast deltaic reservoir undergoing natural [[Drive mechanisms and recovery#Water drive|water drive]]. After several years of production, the better quality channel sands watered out, whereas oil remained in the poorer quality delta fringe deposits. In this field, bypassed oil was accessed by recompleting wells only in the delta fringe interval.

Distributary mouth bars typically contain a high percentage of interstratified clay that reduces [[Directional permeability|vertical permeability]]. Hartman and Paynter<ref name=pt06r50>Hartman, J. A., Paynter, D. D., 1979, [https://www.onepetro.org/journal-paper/SPE-7532-PA Drainage anomalies in Gulf Coast Tertiary sandstones]: Journal of Petroleum Technology, Oct., p. 1313–1322.</ref> document an example of such behavior from a Gulf Coast deltaic reservoir undergoing natural [[Drive mechanisms and recovery#Water drive|water drive]]. After several years of production, the better quality channel sands watered out, whereas oil remained in the poorer quality delta fringe deposits. In this field, bypassed oil was accessed by recompleting wells only in the delta fringe interval.

Wave modification acts to winnow delta mouth bar sandstones thus increasing their reservoir quality. In addition, wave processes and [[longshore currents]] enhance overall reservoir potential in deltas by redistributing sand as beach and [[chenier]] deposits in the interdistributary areas. Tidal reworking can affect reservoir quality at the delta mouth either by acting to winnow fines from the sands or by reducing effective permeability in distributary channels by the introduction of increased amounts of interstratified clay.

Wave modification acts to winnow delta mouth bar sandstones thus increasing their reservoir quality. In addition, wave processes and [[longshore currents]] enhance overall reservoir potential in deltas by redistributing sand as beach and [[chenier]] deposits in the interdistributary areas. Tidal reworking can affect reservoir quality at the delta mouth either by acting to winnow fines from the sands or by reducing effective permeability in distributary channels by the introduction of increased amounts of interstratified clay.