The Jolliet field is believed to be the first development in the offshore U.S. Gulf of Mexico to exploit a major reverse fault trap. With the world's first tension leg well platform (TLWP) set in 1,760 ft (536 m) of water on the upper continental slope, the field has also set a water depth record for a production platform. The field's multiple stacked reservoirs consist of unconsolidated Pleistocene lowstand fan grain flow, debris flow, and turbidite deposits. Regionally, the area is structurally dominated by four major salt diapirs. The field is structurally complicated by an underlying salt ridge, a major syndepositional reverse fault and late normal faults. Reverse fault documentation includes three-dimensional seismic interpretation, repeated paleontological markers, prediction and correlation of up to 3,000 ft (914 m) of repeated pay section as wll as slope stability computer modeling. One well repeated 18 of 23 known reservoir sands in the subthrust. However, syndepositional movement along the fault created an expanded subthrust section relative to the paleohigh of the overthrust section. A structural model is presented, suggesting that the reverse fault developed at the toe of a major salt flank growth fault. The fault was initiated during the lower Pleistocene as themore » sediment slope was diapirically oversteepened. The resultant failure surface was cylindrically constrained by salt at its lateral limits and by higher density Pliocene shale at depth. This model is supported by slope stability computer modeling using realistic sediment strengths, densities, and pore pressure gradients.« less