Page 64 - Fundamentals of Gas Shale Reservoirs
P. 64
44 ORGANIC MATTER‐RICH SHALE DEPOSITIONAL ENVIRONMENTS
Sorby HC. On the application of quantitative methods to the study Trabucho‐Alexandre J. Mesozoic Sedimentation in the North Atlantic
of the structure and history of rocks. Quart J Geol Soc 1908; and Western Tethys; Global Forcing Mechanisms and Local
64:171–233. Sedimentary Processes. Utrecht: Universiteit Utrecht; 2011.
Southam JR, Peterson WH, Brass GW. dynamics of anoxia. Trabucho‐Alexandre J. More gaps than shale: erosion of mud and its
Palaeogeogr Palaeoclim Palaeoecol 1982;40:183–198. effect on preserved geochemical and palaeobiological signals. In:
Southard JB. Representation of bed configurations in depth‐ Smith DG, Bailey RJ, Burgess PM, Fraser AJ, editors. Strata and
velocity‐size diagrams. J Sediment Petrol 1971;41:903–915. Time: Probing the Gaps in Our Understanding, vol. 404. London:
Stanley SM. Earth System History. New York: W.H. Freeman & Geological Society; 2014. DOI:10.1144/SP404.10.
Company; 1999. Trabucho‐Alexandre J, Tuenter E, Henstra GA, van der Zwan KJ, van
Stein R. Organic carbon and sedimentation rate—further evidence de Wal RSW, Dijkstra HA, de Boer PL. The mid‐Cretaceous North
for anoxic deep‐water conditions in the Cenomanian/Turonian Atlantic nutrient trap: black shales and OAEs. Paleoceanography
Atlantic Ocean. Mar Geol 1986;72:199–209. 2010;25:PA4201.
Stein R. Organic carbon content/sedimentation rate relationship Trabucho‐Alexandre J, van Gilst RI, Rodríguez‐López JP, de Boer
and its paleoenvironmental significance for marine sediments. PL. The sedimentary expression of oceanic anoxic event 1b in
Geo‐Marine Lett 1990;10:37–44. the North Atlantic. Sedimentology 2011;58:1217–1246.
Storey M, Duncan RA, Swisher CC. Paleocene‐Eocene thermal Trabucho‐Alexandre J, Dirkx R, Veld H, Klaver G, de Boer PL.
maximum and the opening of the Northeast Atlantic. Science Toarcian Black Shales in the Dutch Central Graben: record of
2007;316:587–589. energetic, variable depositional conditions during an oceanic
Stow DAV. Fine‐grained sediments in deep water: an overview of anoxic event. J Sediment Res 2012a;82:104–120.
processes and facies models. Geo‐Mar Lett 1985a;5:17–23. Trabucho‐Alexandre J, Hay WW, de Boer PL. Phanerozoic envi-
Stow DAV. Deep‐sea clastics: where are we and where are we ronments of black shale deposition and the Wilson Cycle. Solid
going?”. In: Brenchley PJ, Williams BPJ, editors. Sedimentology: Earth 2012b;3:29–42.
Recent Developments and Applied Aspects. London: Geological Trask PD. Origin and Environment of Source Sediments of Petroleum.
Society; 1985b. p 67–93. Houston, TX: Gulf Publishing Company; 1932.
Stow DAV, Reading HG, Collinson JD. Deep seas. In: Reading Trusheim F. Rippeln in Schlick. Nat Museum 1929;59:72–79.
HG, editor. Sedimentary Environments: Processes, Facies and Twenhofel WH. Environments of origin of black shales. AAPG
Stratigraphy. Oxford: Blackwell Publishing; 1996. p 395–453. Bull 1939;23:1178–1198.
Stow DAV, Huc A‐Y, Bertrand P. Depositional processes of black Tyson RV. Sedimentation rate, dilution, preservation and total
shales in deep water. Mar Petrol Geol 2001;18:491–498. organic carbon: some results of a modelling study. Org Geochem
Strøm KM. Land‐locked waters and the deposition of black muds. 2001;32:333–339.
In: Trask PD, editor. Recent Marine Sediments. Tulsa: AAPG; Tyson RV. The “productivity versus preservation” controversy:
1939. p 356–372. cause, flaws, and resolution. In: Harris NB, editor. The
Suess E. Particulate organic carbon flux in the oceans—surface pro- Deposition of Organic‐Carbon‐Rich Sediments: Models,
ductivity and oxygen utilization. Nature 1980;288:260–263. Mechanisms, and Consequences. Tulsa: SEPM; 2005. p 17–33.
Summerhayes CP, de Melo U, Barretto HT. The influence of upwelling van Andel TH, Thiede J, Sclater JG, Hay WW. Depositional his-
on suspended matter and shelf sediments off Southeastern Brazil. tory of the South Atlantic Ocean during the last 125 million
J Sediment Petrol 1976;46:819–828. years. J Geology 1977;85:651–698.
Talbot MR. The origins of lacustrine oil source rocks: evidence van Straaten LMJU. Longitudinal ripple marks in mud and sand.
from the lakes of tropical Africa. In: Fleet AJ, Kelts K, Talbot J Sediment Petrol 1951;21:47–54.
MR, editors. Lacustrine Petroleum Source Rocks. London: Van Waterschoot van der Gracht WAJM. Permo‐carboniferous
Geological Society; 1988. p 29–43. orogeny in South‐Central United States. AAPG Bull 1931;
Talbot MR, Allen PA. Lakes. In: Reading HG, editor. Sedimentary 15:991–1057.
Environments: Processes, Facies and Stratigraphy. Oxford: Walker RG. Nondeltaic depositional environments in the Catskill
Blackwell Publishing; 1996. p 83–124. clastic wedge (Upper Devonian) of central Pennsylvania. Geol
Terwindt JHJ, Breusers HNC. Experiments on the origin of flaser, Soc Am Bull 1971;82:1305–1326.
lenticular and sand‐clay alternating bedding. Sedimentology Walsh JJ. Importance of continental margins in the marine biogeo-
1972;19:85–98. chemical cycling of carbon and nitrogen. Nature 1991;350:53–55.
Tissot B. Effects on prolific petroleum source rocks and major coal Walsh JP, Nittrouer CA. Understanding fine‐grained river‐sediment
deposits caused by sea‐level changes. Nature 1979;277:463–465. dispersal on continental margins. Marine Geol 2009;263:
Topper RPM, Trabucho‐Alexandre J, Tuenter E, Meijer PT. A 34–45.
regional ocean circulation model for the mid‐Cretaceous North Waples DW. Reappraisal of anoxia and organic richness, with
Atlantic Basin: implications for black shale formation. Clim emphasis on Cretaceous of North Atlantic. AAPG Bull 1983;
Past 2011;7:277–297. 67:963–978.
Tourtelot HA. Origin and use of the word “shale”. Am J Sci Weaver CE. Clays, Muds, and Shales. Developments in
1960;258‐A:335–343. Sedimentology 44. Amsterdam: Elsevier; 1989.
