− | Each systems tract—highstand, lowstand, and transgressive—has a different trapping potential based on the vertical and lateral distribution of lithofacies deposited within specific depositional environments. White<ref name=ch04r112>White, D., A., 1980, Assessing oil and gas plays in facies-cycles wedges: AAPG Bulletin, vol. 64, p. 1158–1178.</ref> presents an excellent review of trap types within facies-cycle wedges, which are related to transgressive-regressive cycles and can be related most specifically to the transgressive systems tract and the highstand systems tract. In White's classification, prograding lithofacies of the lowstand systems tract might occur as subunconformity traps or might be mistakenly identified as highstand systems tract deposits. Gravity-flow deposits of slope and basin-floor fan systems are most often placed into the lowstand systems tract because they are deposited basinward of the shelf/slope inflection. | + | Each systems tract—highstand, lowstand, and transgressive—has a different trapping potential based on the vertical and lateral distribution of lithofacies deposited within specific depositional environments. White<ref name=ch04r112>White, D., A., 1980, Assessing oil and gas plays in facies-cycles wedges: AAPG Bulletin, vol. 64, p. 1158–1178.</ref> presents an excellent review of trap types within facies-cycle wedges, which are related to transgressive-regressive cycles and can be related most specifically to the transgressive systems tract and the highstand systems tract. In White's classification, [[Well_log_sequence_analysis#Parasequence_stacking_patterns|prograding]] lithofacies of the lowstand systems tract might occur as subunconformity traps or might be mistakenly identified as highstand systems tract deposits. Gravity-flow deposits of slope and basin-floor fan systems are most often placed into the lowstand systems tract because they are deposited basinward of the shelf/slope inflection. |
| White<ref name=ch04r112 /> discusses both siliciclastic and carbonate systems. Sarg<ref name=ch04r84>Sarg, J., F., 1988, Carbonate [[sequence stratigraphy]]: SEPM Special Publication 42, p. 155–181.</ref> provides an excellent discussion of carbonate systems. Only siliciclastic systems, similar to those of the Cenozoic of the central and western Gulf of Mexico, are discussed here. | | White<ref name=ch04r112 /> discusses both siliciclastic and carbonate systems. Sarg<ref name=ch04r84>Sarg, J., F., 1988, Carbonate [[sequence stratigraphy]]: SEPM Special Publication 42, p. 155–181.</ref> provides an excellent discussion of carbonate systems. Only siliciclastic systems, similar to those of the Cenozoic of the central and western Gulf of Mexico, are discussed here. |
− | Siliciclastic lowstand prograding complexes, imaged on seismic reflection profiles as clinoforms, are often fluvial-deltaic complexes with abundant sand in the depositional topsets (Figures 4-19 and 4-21). As the relative sea level cycle turns around from low to rising, the coarse-grained sediment supply decreases. The fine-grained sediments of the transgressive systems tract overlie the lowstand systems tract–prograding complex sand-prone facies, providing excellent top seal to the underlying sandy reservoir. If the transgressive shales are organic rich and buried in the thermal regime for kerogen cracking, hydrocarbons will be generated. If the lithofacies forming the preceding shelf edge can provide lateral seal, the prograding complex reservoir facies may become charged with hydrocarbons even without structural enhancement of the trap.<ref name=ch04r16>Armentrout, J., M., Rodgers, B., K., Fearn, L., B., Block, R., B., Snedden, J., W., Lyle, W., D., Herrick, D., C., Nwankwo, B., 1997, Application of high resolution biostratigraphy, Oso field, Nigeria: Proceedings, Gulf Coast Section SEPM 18th Annual Research conference, p. 13–20.</ref> | + | Siliciclastic lowstand [[Well_log_sequence_analysis#Parasequence_stacking_patterns|prograding]] complexes, imaged on seismic reflection profiles as clinoforms, are often fluvial-deltaic complexes with abundant sand in the depositional topsets (Figures 4-19 and 4-21). As the relative sea level cycle turns around from low to rising, the coarse-grained sediment supply decreases. The fine-grained sediments of the transgressive systems tract overlie the lowstand systems tract–prograding complex sand-prone facies, providing excellent top seal to the underlying sandy reservoir. If the transgressive shales are organic rich and buried in the thermal regime for kerogen cracking, hydrocarbons will be generated. If the lithofacies forming the preceding shelf edge can provide lateral seal, the prograding complex reservoir facies may become charged with hydrocarbons even without structural enhancement of the trap.<ref name=ch04r16>Armentrout, J., M., Rodgers, B., K., Fearn, L., B., Block, R., B., Snedden, J., W., Lyle, W., D., Herrick, D., C., Nwankwo, B., 1997, Application of high resolution biostratigraphy, Oso field, Nigeria: Proceedings, Gulf Coast Section SEPM 18th Annual Research conference, p. 13–20.</ref> |