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  • Arthur, M. A., The carbon cycle-controls on atmospheric CO2 and climate in the geologic past, Climate in Earth History, Stud. Geophys., 5, 567, AGU, Washington, D. C., 1982.
  • Arthur, M. A., B. B. Sageman, Marine black shales: Depositional mechanisms and environments of ancient deposits, Amu. Rev. Earth Planet. Sci., 22, 499551, 1994.
  • Arthur, M. A., P. A. Scholle, P. Husson, Stable isotopes of oxygen and carbon in carbonates from Sites 398 and 116 of DSDP, Initial Rep. Deep Sea Drill. Proj., 47/2, 477492, 1979.
  • Arthur, M. A., W. E. Dean, D. A. V. Stow, Models for the deposition of Mesozoic — Cenozoic fine-grained organic-carbon-rich sediments in the deep sea, Fine-Grained Sediments: Processes and Products, Geol Soc. London Spec. Publ., 15D. A. V. Stow, D. J. W. Piper, 527562, 1984.
  • Arthur, M. A., W. E. Dean, S. O. Schlanger, Variations in the global carbon cycle during the Cretaceous related to climate, volcanism, and changes in atmospheric CO2, The Carbon Cycle and Atmospheric CO2: Natural Variations Archean to Present, Geophys. Monogr. Ser., 32E. T. Sundquist, W. E. Broecker, 504529, AGU, Washington, D. C., 1985.
  • Arthur, M. A., W. E. Dean, L. M. Pratt, Geochemical and climatic effects of increased marine organic carbon burial at the Cenomanian/Turonian boundary, Nature, 335, 714716, 1988.
  • Arthur, M. A., H. C. Jenkyns, H.-J. Brumsack, S. O. Schlanger, Stratigraphy, geochemistry, and paleoceanography of organic-carbon rich Cretaceous sequences, Cretaceous Resources, Events and RhythmsR. N. Ginsburg, B. Beaudoin, 75119, Kluwer Acad., Norwell, Mass., 1990.
  • Barron, E. J., W. H. Peterson, Mid-Cretaceous ocean circulation: Results from model sensitivity studies, Paleoceanography, 5, 319338, 1990.
  • Barron, E. J., W. M. Washington, Warm Cretaceous climates: High atmospheric CO2 as a plausible mechanism, The Carbon Cycle and Atmospheric CO2: Natural Variations Archean to Present, Geophys. Monogr. Ser., 32E. T. S. Sundquist, W. E. Broecker, 546553, AGU, Washington, D. C., 1985.
  • Bartolini, A., P. O. Baumgartner, J. Hunziker, Middle and Late Jurassic carbon stable isotope stratigraphy and radiolarite sedimentation of the Umbria-Marche Basin (central Italy), Eclogae Geol. Helv., 89, 811844, 1996.
  • Berger, W. H., E. Vincent, Deep sea carbonates: Reading the carbon isotope signal, Geol. Rundschau, 75, 249269, 1986.
  • Berner, R., A. C. Lasaga, R. M. Garrels, The carbonate-silicate geochemical cycle and its effect on atmospheric carbon dioxide over the past 100 million years, Am. J. Sci., 283, 641683, 1983.
  • Bersezio, R., Stratigraphic framework and sedimentary features of the Lower Aptian “Livello Selli” in the Lombardy Basin (Southern Alps, Northern Italy), Riv. Ital. Palaeontol. Strat., 99, 569590, 1994.
  • Beveridge, N. A. S., N. J. Shackleton, Carbon isotopes in recent planktonic foraminifera: A record of anthropogenic CO2 invasion of the surface ocean, Earth Planet. Sci. Lett., 126, 259273, 1994.
  • Borel, G., Préalpes médianes romandes: Courbes de subsidence et implications géodynamiques, Bull. Soc. Vaudoise Sci. Nat., 83, 293315, 1995.
  • Bosellini, A., Modello geodinamico e paleotettonico delie Alpi Meridionali durante il Giurassico-CretacicoSue possibili applicazioni agli Appennini, paper presented at Moderne Vedute sulla Geologia dell'Appennino, 370, 163–213Accad. Naz. Lincei, 1973.
  • Bottinga, Y., Calculation of fractionation factors for carbon and oxygen isotope exchange in the system calcite-carbon dioxide-water, J. Phys. Chem., 72, 800808, 1968.
  • Bralower, T. J., Valanginian to Aptian calcareous nannofossil stratigraphy and correlation with upper M-sequence magnetic anomalies, Mar. Micropaleontol., 11, 293310, 1987.
  • Bralower, T. J., H. R. Thierstein, Organic carbon and metal accumulation rates in Holocene and mid-Cretaceous sediments: Palaeoceanographic significance, Marine Petroleum Source Rocks, Spec. Publ. Geol. Soc. London, 26J. Brooks, A. J. Fleet, 345369, 1987.
  • Bralower, T. J., W. V. Sliter, M. A. Arthur, R. M. Leckie, D. J. Allard, S. O. Schlanger, Dysoxic/anoxic episodes in the Aptian-Albian (Early Cretaceous), The Mesozoic Pacific: Geology, Tectonics, and Volcanism, Geophys. Monogr. Ser., 77M. S. Pringle, et al., 537, AGU, Washington, D. C., 1993.
  • Bralower, T. J., M. A. Arthur, R. M. Leckie, W. V. Sliter, D. J. Allard, S. O. Schlanger, Timing and paleoceanography of oceanic dysoxia/anoxia in the late Barremian to early Aptian, Palaios, 9, 335369, 1994.
  • Bréhéret, J.-G., The mid-Cretaceous organicrich sediments from the Vocontian Zone of the French Southeast Basin, Hydrocarbon and Petroleum Geology of France, Spec. Publ. Eur. Assoc. Petrol. Geol., 4A. Mascle, 295320, 1994.
  • Brown, R., P. Farrimond, R. V. Tyson, A. P. Menegatti, H. Weissert, A molecular and isotopic geochemical study of the Aptian Oceanic Anoxic Event on the western Tethyan marginspaper presented at the Research Conference: Carbonates and Global Change: An Interdisciplinary Approach, Soc. for Sediment.Geol. Int. Assoc. Sediment.Wildhaus, Switzerland, June 22–27, 1996.
  • Caldeira, K., M. R. Rampino, The mid-Cretaceous super plume, carbon dioxide, and global warming, Geophys. Res. Lett., 18, 987990, 1991.
  • Channell, J. E. T., W. Lowrie, F. Medizza, Middle and Early Cretaceous magnetic stratigraphy from the Cismon section, northem Italy, Earth Planet. Sci. Lett., 42, 153166, 1979.
  • Clauser, S., M. Renard, G. Richebois, Variation in trace element contents and iso-topic compositions of Lower Cretaceous carbonates from the Galicia margin (ODP Leg 103): Reconstruction of the pafeochemistry of the Early Cretaceous Ocean, Proc. Ocean Drill. Program Sci. Results, 103, 489504, 1988.
  • Coccioni, R., O. Nesci, M. Tramontana, C. F. Wezel, E. Moretti, Descrizione di un livello guida “Radiolaritico-Bituminoso-Ittiolitico” alia base délie Marne a Fucoidi neul Appennino Umbro-Marchigiano, Boll. Soc. Geol. Ital, 106, 183192, 1987.
  • Coccioni, R., R. Franchi, O. Nesci, C. F. Wezel, F. Battistini, P. Pallecchi, Stratigraphy and mineralogy of the Selli level (early Aptian) at the base of the Marne a Fucoidi in the Umbrian-Marchean Apennines (Italy), Cretaceous of Western Tethys, 3rd International Cretaceous SymposiumJ. Weidmann, 563584, Schweizerbart'sche, Stuttgart, Germany, 1989.
  • Coccioni, R., E. Erba, I. Premoli-Silva, Barremian-Aptian calcareous plankton bios-tratigraphy from the Gorgo Cerbara section (Marche, central Italy) and implications for plankton evolution, Cretaceous Res., 13, 517537, 1992.
  • Coplen, T. B., Reporting of stable hydrogen, carbon, and oxygen isotopic abundances, Pure Appl Chem., 66, 273276, 1994.
  • Corfield, R. M., Paleocene oceans and climate: An isotopic perspective, Earth Sci. Rev., 37, 225252, 1994.
  • Corfield, R. M., J. E. Cartlidge, Wholerock oxygen and carbon isotope stratigraphy of the Paleogene and Cretaceous/Tertiary boundary in ODP Hole 807C, Proc. Ocean Drill Program Sci. Results, 130, 259268, 1993.
  • Corfield, R. M., J. E. Cartlidge, I. Premoli-Silva, R. A. Housley, Oxygen and carbon isotope stratigraphy of the Palaeogene and Cretaceous limestones in the Bottaccione Gorge and the Contessa Highway sections, Umbria, Italy, Terra Nova, 3, 414422, 1991.
  • Cotillon, P., M. Rio, Cyclic sedimentation in the Cretaceous of DSDP Sites 535 and 540 (Gulf of Mexico), 534 (central Atlantic) and the Vocontian Basin (France), Initial Rep. Deep Sea Drill. Proj., 77, 339376, 1984.
  • Craig, H., The geochemistry of the stable carbon isotopes, Geochim. Cosmochim. Acta, 3, 5392, 1953.
  • Cresta, S., S. Monechi, G. Parisi, Stratigrafia del Mesozoico e Cenozoico nell'area Umbro-Marchigiana (Mesozoic-Cenozoic Stratigraphy in the Umbria-Marche Area), Mem. Desc. Delia Carta Geol. d'ltalia, 39, 1185, Ist. Poligrafico e Zecca dello Stato, Rome, 1989.
  • Dean, W. E., M. A. Arthur, G. E. Claypool, Depletion of 13C in Cretaceous marine organic matter: Source, diagenetic or environmental signal?, Mar. Geol., 70, 119157, 1986.
  • Dupasquier, C., B. Ligouis, M. Caron, The organic matter of “mid Cretaceous” deposits of the Median Prealps, Cretaceous of Western Tethys, 3rd International Cretaceous SymposiumJ. Weidmann, 607635, Schweizerbart'sche, Stuttgart, Germany, 1989.
  • Emrich, K., E. H. Ehalt, J. C. Vogel, Carbon isotope fractionation during the precipitation of calcium carbonate, Earth Planet. Sci. Lett., 8, 363371, 1970.
  • Erba, E., Aptian-Albian calcareous nannofossil biostratigraphy of the Scisti a Fucoidi cored at Piobbico (central Italy), Riv. Ital. Paleontol. Strat., 94, 249284, 1988.
  • Erba, E., Nannofossils and superplumes: The early Aptian “nannoconid crisis”, Paleoceanography, 9, 483501, 1994.
  • Erba, E., The Aptian stage, Bull. Inst. R. Sci. Nat. Belg. Sci. Terre, 66, 3143, 1996.
  • Erba, E., R. Coccioni, andI. Premoli Silva, The “Scisti a Fucoidi” in the Umbria-Marche area: The Apecchiese road section, in Stratigrafia del Mesozoico e Cenozoico nel-Varea Umbro-Marchigiana (Mesozoic-Cenozoic Stratigraphy in the Umbria-Marche area), Mem. Desc. Delia Carta Geol. d'ltalia, vol. 39, edited byS. Cresta, et al. 99. 146164, Ist. Poligrafico e Zecca dello Stato, Rome, 1989.
  • Erbacher, J., Entwicklung und Paläozeanographie mittelkretazischer Radiolarien der westlichen Tethys (Italien) und des Nordatlantiks, Tübinger Mikropaläontol. Mitt., 12, 88, 1994.
  • Erbacher, J., J. Thurow, Influence of oceanic anoxic events on the evolution of mid-Cretaceous radiolaria in the North Atlantic and western Tethys, Mar. Micropaleontol., 30, 139158, 1997.
  • Erbacher, J., J. Thurow, R. Littke, Evolution patterns of radiolaria and organic matter variations: A new approach to identify sea-level changes in mid-Cretaceous pelagic environments, Geology, 24, 499502, 1996.
  • Ferreri, V., H. Weissert, B. D' Argenio, F. P. Buonocunto, Carbon-isotope stratigraphy.: A tool for basin to carbonate platform correlation, Terra Nova, 9, 5761, 1997.
  • Föllmi, K. B., 160 m.y. record of marine sedimentary phosphorous burial: Coupling of climate and continental weathering under greenhouse and icehouse conditions, Geology, 23, 859862, 1995.
  • Föllmi, K. B., H. Weissert, M. Bisping, H. P. Funk, Phosphogenesis, carbon-isotope stratigraphy and carbonate-platform evolution along the Lower Cretaceous northern Tethyan margin, Geol. Soc. Am. Bull., 106, 729746, 1994.
  • Fouke, B. W., W. Schlager, Mid-Cretaceous Carbon-isotope stratigraphy: A facies-breaking record of global environmental change in Russia, Ukraine, and Italypaper presented at the Research Conference: Carbonates and Global change: An Interdisciplinary ApproachSoc. for Sediment. Geol. Int. Assoc. Sediment.Wildhaus, Switzerland, June 22–27, 1996.
  • Gérard, J.-C., V. Dols, The warm Cretaceous climate: Role of the long-term carbon cycle, Geophys. Res. Lett., 17, 15611564, 1990.
  • Grötsch, J., I. M. Billing, E. J. Oswald, Carbon isotope records in Lower Cretaceous shallow water carbonates: Stratigraphic and palaeoceanographic implicationspaper presented at the Research Conference: Carbonates and Global change: An Interdisciplinary Approach, Soc. for Sediment.Geol. Int. Assoc. Sediment.Wildhaus, Switzerland, June 22–27, 1996.
  • Hable, R., Biostratigraphie, Sedimentologie und paläozeanographische Entwicklung der Préalpes Médianes des Chablais (Haute Savoie) im Zeitabschnitt vom Apt bis Unter-Eozän, Ph.D. dissertation, Univ. de Fribourg, Fribourg, Switzerland, 1997.
  • Hadji, S., Stratigraphic isotopique des carbonates pelagiques (Jurassique supérieur-Crétacé inférieur) du Bassin d' Ombrie-Marches (Italie), Ph.D. dissertation, Univ. Pierre et Marie Curie, Paris, France. 1991.
  • Hasegawa, T., Cenomanian-Turonian carbon isotope events recorded in terrestrial organic matter from northern Japan, Palaeogeogr. Palaeoclimatol. Palaeoecol., 130, 251273, 1997.
  • Hauck, J., Paläomagnetische Untersuchungen an ausgewählten Profilen der Kreide in der Rhenodanubischen Flysch-Zone, Ph.D. dis-sertation, Univ. Ludwig-Maximilians, Munich, Germany, 1997.
  • Hay, W. W., Cretaceous paleoceanography, Geol. Carpathica, 46, 257266, 1995.
  • Hay, W. W., C. N. Wold, The effect of changes of the mean salinity on ocean circulation, Miner. Slovaca, 29, 243244, 1997.
  • Hayes, J. M., B. N. Popp, R. Takigiku, M. W, Johnson, An isotopic study of biogeo-chemical relationships between carbonates and organic carbon in the Greenhorn Formation, Geochim. Cosmochim. Acta, 53, 29612972, 1989.
  • Herbert, T. D., Paleomagnetic calibration of Milankovitch cyclicity in Lower Cretaceous sediments, Earth Planet. Sci. Lett., 112, 1528, 1992.
  • Herbert, T. D., J. L. Sarmiento, Ocean nutrient distribution and oxygénation: Limits on the formation of warm saline bottom water over the past 91 m.y., Geology, 19, 702705, 1991.
  • Herman, A. B., R. A. Spicer, Palaeobotanical evidence for a warm Cretaceous Arctic Ocean, Nature, 380, 330333, 1996.
  • Holser, W. T., M. Magaritz, J. Wright, Chemical and isotopic variations in the world ocean during Phanerozoic time, Global Bio-eventsO. Walliser, 6374, Springer, New York, 1986.
  • Huber, B. T., D. A. Hodell, C. P. Hamilton, Middle-Late Cretaceous climate of the southern high latitudes: Stable isotopic evidence for minimal equator-to-pole thermal gradients, Bull Geol. Soc. Am., 107, 11641191, 1995.
  • Hudson, J. D., Stable isotopes and limestone lithification, J. Geol. Soc. London, 133, 637660, 1977.
  • Irwin, H., C. Curtis, M. Coleman, Isotopic evidence for source of diagenetic carbonates formed during burial of organic-rich sediments, Nature, 269, 209213, 1977.
  • Jacobs, E., H. Weissert, G. Shields, P. Stille, The Monterey event in the Mediterranean: A record from shelf sediments of Malta, Paleoceanography, 11, 717728, 1996.
  • Jenkyns, H. C., Origin of red nodular limestones (Ammonitico Rosso, Knollenkalke) in the Mediterranean Jurassic: A diagenetic model, Pelagic Sediments on Land and Under the Sea, Spec. Publ. Int. Assoc. Sedimentol., 1K. J. Hsü, H. C. Jenkyns, 49271, Blackwell, Cambridge, Mass., 1974.
  • Jenkyns, H. C., Cretaceous anoxic events: From continents to oceans, J. Geol. Soc. London, 137, 171188, 1980.
  • Jenkyns, H. C., Carbon-isotope stratigraphy and paleoceanographic significance of the Lower Cretaceous shallow-water carbonates of resolution Guyot, Mid-Pacific mountains, Proc. Ocean Drill. Program Sci. Results, 143, 99104, 1995.
  • Jenkyns, H. C., Relative sea-level change and carbon isotopes: Data from the Upper Jurassic (Oxfordian) of central and Southern Europe, Terra Nova, 8, 7585, 1996.
  • Jenkyns, H. C., C. J. Clayton, Black shales and carbon isotopes in pelagic sediments from the Tethyan Lower Jurassic, Sedimentology, 33, 87106, 1986.
  • Jenkyns, H. C., A. S. Gale, R. M. Corfield, Carbon and oxygen-isotope stratigraphy of the English Chalk and Italian Scaglia and its palaeoclimatic significance, Geol. Mag., 131, 134, 1994.
  • Karhu, J. A., H. D. Holland, Carbon isotopes and the rise of atmospheric oxygen, Geology, 24, 867870, 1996.
  • Kempe, S., J. Kazmierczak, The role of alkalinity in the evolution of ocean chemistry, organization of living systems, and biocalcification processes, Bull. Inst. Océanogr., 13, 61117, 1994.
  • Kump, L. R., Interpreting carbon isotope excursions: Strangelove oceans, Geology, 19, 299302, 1991.
  • Lambert, E., P. De Wever, Événements biologiques chez les radiolaires au cours des phases kénoxiques du Crétacé, Rev. Micropaleontol., 39, 283292, 1996.
  • Larson, R. L., Latest pulse of Earth: Evidence for a mid-Cretaceous superplume, Geology, 19, 547550, 1991a.
  • Larson, R. L., Geological consequences of superplumes, Geology, 19, 963966, 1991b.
  • Leckie, R. M., A paleoceanographic model for the early evolutionary history of planktonic foraminifera, Palaeogeogr. Palaeoclimatol. Palaeoecol., 73, 107138, 1989.
  • Létolle, R., C. Vergnaud-Grazzini, C. Pierre, Oxygen and carbon isotopes from bulk carbonates and foraminiferal shells at DSDP Sites 400 and 406, Initial Rep. Deep Sea Drill. Proj., 48, 741755, 1979.
  • Lini, A., Early Cretaceous carbon isotope stratigraphy of the Maiolica Formation, Southern Alps (northern Italy and southern Switzerland): Stratigraphic and paleoenvironmental significance, Ph.D. dissertation, 259 pp, Eidg. Techn. Hochsch., Zürich, Switzerland, 1994.
  • Lini, A., H. Weissert, E. Erba, The Valanginian carbon isotope event: A first episode of greenhouse climate conditions during the Cretaceous, Terra Nova, 4, 374384, 1992.
  • Lintnerovà, O., J. Michailik, D. Rehakovà, M. Petercàkovà, E. Halasovà, J. Hladikovà, Sedimentary and isotopic record of the Aptian anoxic “Selli” event in the Pieniny Klippen Belt, Slovakia, Miner. Slovaca, 29, 315316, 1997.
  • Mackenzie, F. T., Sedimentary cycling and the evolution of seawater, Chemical Oceanography 2nd ed.,, 1J. P. Riley, G. Skirrow, 309364, Academic, San Diego, Calif, 1975.
  • Magaritz, M., R. V. Krishnamurthy, W. Holser, Parallel trends in organic and inorganic carbon isotopes across the Permian-Triassic boundary, Am. J. Sci., 292, 727739, 1992.
  • Manabe, S., K. Bryan, CO2-induced change in a coupled ocean-atmosphere model and its paleoclimatic implication, J. Geophys. Res., 90, 1168911707, 1985.
  • Marconi, M., F. C. Wezel, A. Longinelli, A stable isotope study of a calcareous-black shale series from the Barremian-Aptian of the northern Apennines, Umbro-Marchean succession, Italy, Miner. Petrogr. Acta, 37, 211218, 1994.
  • Marshall, J. D., Stable isotope evidence for the environment of lithification of some Tethyan limestones, Neues Jahrb. Geol. Paläontol Monatsh., 4, 211224, 1981.
  • Matter, A., R. G. Douglas, K. Perch-Nielsen, Fossil preservation, geochemistry and diagenesis of pelagic carbonates from Shatsky Rise, northwest Pacific, Initial Rep. Deep Sea Drill Proj., 32, 891921, 1975.
  • McCrea, J. M., The isotopic chemistry of carbonates and a paleotemperature scale, J. Chem. Phys, 18, 849857, 1950.
  • McKenzie, J. A., D. Bernoulli, R. E. Garrison, Lithification of pelagichemipelagic sediments at DSDP Site 372: Oxygen isotope alteration with diagenesis, Initial Rep. Deep Sea Drill. Proj., 42A, 473478, 1978.
  • Menegatti, A. P., R. Nüesch, Influence of organic matter on smectite illite transformation in carbonatespaper presented at the 11th International Clay ConferenceClay Minerals SocietyOttawa, Ont. Can.June 15–21, 1997.
  • Mizutani, H., E. Wada, Effect of high atmospheric CO2 on δ13C of algae, Origin Life, 12, 377390, 1982.
  • Ogg, J. G., A. H. F. Robertson, L. F. Jansa, Jurassic sedimentation history of Site 534 (western North Atlantic) and of the Atlantic-Tethys Seaway, Initial Rep. Deep Sea Drill. Proj., 76, 829884, 1983.
  • Opdyke, B. N., Apticore Project-Cismon Core: A high-resolution stable isotope record through the middle Aptian carbon isotope excursion, a chemostratigraphic type section, Eos Trans., AGU, 78Fall Meet. Suppl., F371, 1997.
  • Page, C., Observations géologiques sur les Préalpes au NW des Gastlosen orientales, Bull. Soc. Frib. Sci. Nat., 58, 83177, 1969.
  • Parrish, J. T., R. L. Curtis, Atmospheric circulation, upwelling and organic-rich rocks in the Mesozoic and Cenozoic eras, Palaeogeogr. Palaeoclimatol. Palaeoecol., 40, 3166, 1982.
  • Patton, J. W., P. W. Choquette, G. K. Guennel, A. J. Kaltenback, A. Moore, Organic geochemistry and sedimentology of Lower to mid-Cretaceous deep-sea carbonates, Sites 535 and 540, Leg 77, Initial Rep. Deep Sea Drill. Proj., 77, 417443, 1984.
  • Pedersen, T. F., S. E. Calvert, Anoxia vs. Productivity: What controls the formation of organic-carbon-rich sediments and sedimentary rocks?, AAPG Bull, 74, 454466, 1990.
  • Popp, N. B., R. Takigiku, J. M. Hayes, J. W. Louda, E. W. Baker, The post-Paleozoic chronology and mechanism of 13C depletion in primary organic matter, Am. J. Sci., 289, 436454, 1989.
  • Pratt, L. M., Isotopic studies of organic matter and carbonate in rocks of the Greenhorn marine cycle, Fine-Grained Deposits and Biofacies of Cretaceous Western Interior Seaway: Evidence of Cyclic Sedimentary Processes, Soc. Econ. Paleontol. Mineral, Tulsa Field Trip Guidebook, 4L. M. Pratt, et al., 3848, 1985.
  • Pratt, L. M., J. D. King, Variable marine productivity and high eolian input recorded by rhythmic black shales in mid-Cretaceous pelagic deposits from central Italy, Paleoceanography, 1, 507522, 1986.
  • Premoli-Silva, I., E. Erba, M. E. Tornaghi, Paleoenvironmental signals and changes in surface fertility in mid Cretaceous Corg-rich facies of the Fucoid Marls (central Italy), Géobios Mém., 11, 225236, 1989.
  • Python-Dupasquier, C., La Formation de l'Intyamon (“Crétacé Moyen”) des Préalpes Médianes Romandes, Ph.D. dissertation, 197 pp., Univ. de Fribourg, Fribourg, Switzerland, 1990.
  • Raiswell, R., R. A. Berner, Organic carbon losses during burial and thermal maturation of normal marine shales, Geology, 15, 853856, 1987.
  • Rau, G. H., T. Takahashi, D. J. Des Marais, Latitudinal variations in plankton δ13C: Implications for CO2 and productivity in past oceans, Nature, 341, 516518, 1989.
  • Renard, M., Pelagic carbonate stratigraphy (Sr, Mg, 18O, 13C), Mar Micropaleontol., 10, 117164, 1986.
  • Rind, D., M. Chandler, Increased ocean heat transport and warmer climate, J. Geophys. Res., 96, 74377461, 1991.
  • Sarmiento, J. L., T. Herbert, J. R. Toggweiler, Causes of anoxia in the world ocean, Global Biogeochem. Cycles, 2, 115128, 1988.
  • Savin, S., The history of the Earth's surface temperature during the past 100 million years, Annu. Rev. Earth Planet. Sci., 5, 319355, 1977.
  • Schidlowski, M., Application of stable carbon isotopes to early biochemical evolution on earth, Annu. Rev. Earth Planet. Sci., 15, 4772, 1987.
  • Schlanger, S., H. C. Jenkyns, Cretaceous anoxic events: Causes and consequences, Geol. Mijnbouw, 55, 179184, 1976.
  • Schlanger, S., M. A. Arthur, H. C. Jenkyns, P. A. Scholle, The Cenomanian-Turonian oceanic anoxic event, I., Stratigraphy and distribution of organic carbon-rich beds and the marine δ13C excursion, Marine Petroleum Source Rocks, Spec. Publ. Geol. Soc. London, 26J. Brooks, A. J. Fleet, 371399, Blackwell, Cambridge, Mass., 1987.
  • Schmidt, G. A., L. A. Mysak, Can increased poleward oceanic heat flux explain the warm Cretaceous climate?, Paleoceanography, 11, 579593, 1996.
  • Schmilz, B., S. D. Charisi, E. I. Thompson, R. P. Speijer, Barium, SiO2 (excess), and P2O5 as proxies of biological productivity in the Middle East during the Paleocene and the latest Paleocene benthic extinction event, Terra Nova, 9, 9599, 1997.
  • Scholle, P., M. A. Arthur, Carbon isotopic fluctuations in pelagic limestones: Potential stratigraphie and petroleum exploration tool, AAPG Bull., 64, 6787, 1980.
  • Shackleton, N. J., The carbon isotope record of the Cenozoic: History of organic carbon burial and of oxygen in the ocean and atmosphere, Marine Petroleum Source Rocks, Geol. Soc. Spec. Publ. London, 26J. Brooks, A. Fleet, 423434, Blackwell, Cambridge, Mass., 1987.
  • Shackleton, N. J., M. A. Hall, Carbon isotope data from Leg 74 sediments, Initial Rep. Deep Sea Drill Proj., 74, 613619, 1984.
  • Shackleton, N. J., M. A. Hall, U. Bleil, R. G. Heath, L. H. Buckle, et al., Carbon isotope stratigraphy Site 577, Initial Rep. Deep Sea Drill. Proj., 86, 503512, 1985.
  • Sliter, W. A., Aptian anoxia in the Pacific Basin, Geology, 17, 909910, 1989.
  • Stampfli, G. M., Le Briançonnais, terrain exotique dans les Alpes?, Eclogae Geol. Helv., 86, 145, 1993.
  • Stampfli, G. M., M. Marthaler, Divergent and convergent margins in the northwestern alps confrontation to actualistic models, Geodin. Acta, 4, 159184, 1990.
  • Tarduno, J. A., W. V. Sliter, L. Kroenke, M. Leckie, H. Mayer, J. J. Mahoney, R. Musgrave, M. Storey, E. L. Winterer, Rapid formation of Ontong-Java Plateau by Aptian mantle plume volcanism, Science, 254, 399403, 1991.
  • Thierstein, H. R., Paleoceanographic implications of organic carbon and carbonate distributions in Mesozoic deep-sea sediments, Deep Drilling in the Atlantic Ocean: Continental Margins and Paleoenvironment, Maurice Ewing Ser., 3M. Talwani, W. Hay, W. B. F. Ryan, 249274, AGU, Washington D. C., 1979.
  • Tyson, R. V., Sedimentary Organic Matter: Organic Fades and Palynofacies, 615, Chapman and Hall, New York, 1995.
  • Tyson, R. V., B. M. Funnell, European Cretaceous shorelines, stage by stage, Palaeogeogr. Palaeoclimatol. Palaeoecol., 59, 6991, 1987.
  • Vahrenkamp, V. C., Carbon isotope stratigraphy of the Upper Kharaib and Shuaiba formations: Implications for the Early Cretaceous evolution of the Arabian Gulf region, AAPG Bull, 80, 647662, 1996.
  • Weissert, H., C-isotope stratigraphy, a monitor of paleoenvironmental change: A case study from the Early Cretaceous, Surv. Geophys., 10, 161, 1989.
  • Weissert, H., Siliciclastics in the Early Cretaceous Tethys and North Atlantic Oceans: Documents of periodic Greenhouse climate conditions, Mem. Soc. Geol. Ital., 44, 5969, 1990.
  • Weissert, H., D. Bernoulli, A transform margin in the Mesozoic Tethys: Evidence from the Swiss Alps, Geol. Rundschau, 74, 665679, 1985.
  • Weissert, H., J. Bréhéret, A carbonate carbon-isotope record from Aptian-Albian sediments of the Vocontian Trough, Bull. Soc. Geol. France, 162, 11331140, 1991.
  • Weissert, H., A. Lini, Ice Age interludes during the time of Cretaceous greenhouse climate?, Controversies in Modern GeologyD. W. Müller, et al., 173191, Academic, San Diego, Calif., 1991.
  • Weissert, H., H. Mohr, Late Jurassic climate and its impact on carbon cycling, Palaeogeogr. Palaeoclimatol. Palaeoecol., 122, 2743, 1996.
  • Weissert, H., J. A. McKenzie, P. Hochuli, Cyclic anoxic events in the Early Cretaceous Tethys Ocean, Geology, 7, 147151, 1979.
  • Weissert, H., J. A. Mc Kenzie, J. E. T. Channell, Natural variations in the carbon cycle during the Early Cretaceous, The Carbon Cycle and Atmospheric CO2: Natural Variations Archean to Present, Geophys. Monogr. Ser., 32E. T. Sundquist, W. E. Broecker, 531545, AGU, Washington, D. C., 1985.
  • Weissert, H., A. Lini, K. B. Fourni, O. Kuhn, Correlation of Early Cretaceous carbon isotope stratigraphy and platform drowning events: A possible link?, Palaeogeogr, Palaeoclimatol Palaeoecol., 137, 189203, 1998.
  • Wezel, F. C., Faciès anossiche ed episodi geotettonici globali, G. Geol., Ser. 3a., 47, 281286, 1985.