Winker, C.D., and Buffler, R.T., 1988, Paleogeographic evolution of early deep-water Gulf of Mexico and margins, Jurassic to Middle Cretaceous (Comanchaean): AAPG Bulletin, v. 72, p. 318-346. Wood, M.L., and Walper, J.L., 1974, The evolution of the interior Mesozoic basin and the Gulf of Mexico: GCAGS Trans., v. 24, p. 31-41. Woods, D.J., 1963, Fractured chalk oil reservoirs, Sabine Parish, Louisiana: GCAGS Trans., v. 13, p. 127-138. Yurewicz, D.A., Marler, T.B., Meyerholtz, K.A., and Siroky, F.X., 1993, Early Cretaceous carbonate platform, north rim of the Gulf of Mexico, Mississippi and Louisiana, in J. A. Toni Simo, R. W. Scott, and J. P. Masse, eds., Cretaceous carbonate platforms: AAPG Memoir 56, p. 81-96. Zimmerman, R.K., 1992, Fractured Smackover Limestone in northeast Louisiana, implication for hydrocarbon exploitation: GCAGS Trans., v. 42, p. 401-412. Zimmerman, R.K., 1995, Evidence and effects of wrench faulting, north central Gulf Coast region: GCAGS Trans., v. 45, p. 629-635. Zimmerman, R.K., and R. Sassen, 1993, Hydrocarbon transfer pathways from Smackover source rocks to younger reservoir traps in the Monroe Gas Field, northeast Louisiana: Gulf Coast Association of Geological Societies Transactions, v. 43, p. 473-480. Zimmerman, R.K., 1998, Chronology of oil generation in Louisiana's fractured Austin Chalk deep horizontal drilling trend: GCAGS Trans., v. 48, p. 517-525. 465
Zimmerman, R.K., 1999a, A potential Louisiana Haynesville-Cotton Valley pinnacle reef trend predicted from palinspastic reconstructions (abs.): AAPG Annual Convention Proceedings, San Antonio, Texas, p. A-160. Zimmerman, R.K., 1999b, Potential oil generation capacity of the north Louisiana hydrocarbon system: GCAGS Trans., v. 49, p. 532-540. Zimmerman, R.K., 2000, Predicting a north Louisiana Jurassic pinnacle reef trend from palinspastic reconstruction: Louisiana State University Basin Research Institute Bulletin, v. 9, p. 1-17. Zimmerman, R.K., and Goddard, D. A., 2001, A north Louisiana gas-prone Hosston slope-basin sand trend: GCAGS Trans., v. 51, p. 423-432. Zimmerman, R.K., and Sassen, R.A., 1993, Hydrocarbon migration pathways from Smackover source rocks to younger reservoir traps in the Monroe Gas Field, northeast Louisiana: GCAGS Trans., v. 43, p. 473-480. 466
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time frame spanning from approximat
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the same well, Pennsylvanian plant
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Louann Salt The Louann Salt conform
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Norphlet deposition, in southern Ar
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Haynesville-Buckner Formation Produ
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Caddo, Bossier, Webster, Claiborne,
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Smackover limestone. The Bossier gr
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Lower Cretaceous Coahuila (Hosston,
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system that includes a variety of d
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greater than 90 md, most of the Tra
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contains approximately 13 producing
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Pine Island shale, averaging 250 ft
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10%. Calcite-lined vugs and intergr
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Lake Anhydrite was deposited above
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Sabine, Franklin, Tensas Shallow wa
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Across northern Louisiana in the pr
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Taylor Group Producing Parishes Cad
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2,000 to 2,500 ft with net pay of 1
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productive in east-central Louisian
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North Louisiana Salt Basin. The str
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Louisiana Salt Basin. Lower Cretace
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Table 2. Oil and gas production for
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1987; Claypool and Mancini, 1989; M
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Figure 329. Cross section A-A’. G
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generation (Table 4). The following
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Table 5. Cotton Valley-Bossier Grou
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Table 6. Cotton Valley-Group sample
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Table 7. Wells used to construct th
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Figure 336. Electric logs for wells
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Figure 338. Thin section micrograph
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Figure 340. Amoco CZ 5-7 well elect
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Table 9. Total organic carbon, rock
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Figure 343. HI versus OI diagram. T
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Figure 345. Rock-Eval pyrolysis ana
- Page 69 and 70: Figure 347. Visual kerogen analyses
- Page 71 and 72: gas with some oil, not only within
- Page 73 and 74: Figure 350. Burial history profile
- Page 75 and 76: Figure 352. Hydrocarbon expulsion p
- Page 77 and 78: Figure 354. (A) Thermal-maturity an
- Page 79 and 80: Figure 356. Cross section A-A’ sh
- Page 81 and 82: Figure 360. Cross section J-J’ sh
- Page 83 and 84: Figure 364. Seismic cross section B
- Page 85 and 86: of secondary, non-associated thermo
- Page 87 and 88: RESULTS AND DISCUSSION Geologic His
- Page 89 and 90: peripheral fault trend and numerous
- Page 91 and 92: oundary between thick transitional
- Page 93 and 94: Cretaceous reservoirs have shown th
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- Page 97 and 98: Reservoir Assessment Comparison of
- Page 99 and 100: For example, Upper Cretaceous sands
- Page 101 and 102: The Upper Jurassic to Lower Cretace
- Page 103 and 104: Bishop, W.F., 1968, Petrology of up
- Page 105 and 106: Dawson, W.C., and Callender, C.A.,
- Page 107 and 108: Fisher, W.L., and McGowen, J.H., 19
- Page 109 and 110: Hermann, L.A., J.A. Lott, and R.E.
- Page 111 and 112: Mancini, E.A., M. Badali, T.M. Puck
- Page 113 and 114: McCulloh, R.P., and Eversull, L.G.,
- Page 115 and 116: Source Rock Potential of Carbonate
- Page 117 and 118: Salvador, A., 1991b, Triassic-Juras
- Page 119: Tolson, J.S., C.W. Copeland, and B.
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