Climate change Earth pronouncedly warmed just before the beginning of OAE2. The Cenomanian-Turonian interval represents one of the hottest intervals of the entire
Phanerozoic eon, and it boasted the highest carbon dioxide concentrations of the Cretaceous period. Even before OAE2, during the late Cenomanian, tropical
sea surface temperatures (SSTs) were very warm, about 27-29 °C. The onset of OAE2 was concurrent with a 4-5 °C rise in shelf sea temperatures. Mean tropical SSTs during OAE2 have been conservatively estimated to have been at least 30 °C, but may have reached as high as 36 °C. Minimum SSTs in mid-latitude oceans were >20 °C. This exceptional warmth persisted until the Turonian-Coniacian boundary. One possible cause of this hothouse was sub-oceanic volcanism. During the middle of the Cretaceous period, the rate of crustal production reached a peak, which may have been related to the rifting of the newly formed
Atlantic Ocean. It was also caused by the widespread melting of hot
mantle plumes under the
ocean crust, at the base of the
lithosphere, which may have resulted in the thickening of the oceanic crust in the
Pacific and
Indian Oceans. The resulting volcanism would have sent large quantities of carbon dioxide into the atmosphere, leading to an increase in global temperatures. Greenhouse gas release was further increased by the degassing of organic-rich sediments intruded into by volcanic sills. Several independent events related to
large igneous provinces (LIPs) occurred around the time of OAE2. A multitude of LIPs were active during OAE2: the
Madagascar,
Caribbean, Gorgona,
Ontong Java, The abundance of LIPs at this time reflects a major overturning in
mantle convection. Trace metals such as
chromium (Cr),
scandium (Sc),
copper (Cu) and
cobalt (Co) have been found at the Cenomanian-Turonian boundary, which suggests that an LIP could have been one of the main basic causes involved in the contribution of the event. The timing of the peak in trace metal concentration coincides with the middle of the anoxic event, suggesting that the effects of the LIPs may have occurred during the event, but may not have initiated the event. Other studies linked the
lead (Pb)
isotopes of OAE-2 to the Caribbean-Colombian and the Madagascar LIPs. An osmium isotope excursion coeval with OAE2 strongly suggests submarine volcanism as its cause; in the Pacific, an unradiogenic osmium spike began about 350 kyr before the onset of OAE2 and terminated around 240 kyr after OAE2's beginning; the osmium isotope data from a highly expanded OAE2 interval in southern Tibet show multiple osmium excursions with the most pronounced one lagging the onset of OAE2 by ≈50 kyr that was probably related to the ocean connectivity change at ~94.5 Ma. Osmium data also reveal that three distinct pulses of intense volcanism occurred ~60, ~270, and ~400 kyr after OAE2's onset, prolonging it. Positive
neodymium isotope excursions provide additional indications of pervasive volcanism as a cause of OAE2. Enrichments in
zinc further bolster and reinforce the existence of extensive hydrothermal volcanism, The absence of geographically widespread
mercury (Hg) anomalies resulting from OAE2 has been suggested to be because of the limited dispersal range of this heavy metal by submarine volcanism. A modeling study performed in 2011 confirmed that it is possible that a LIP may have initiated the event, as the model revealed that the peak amount of carbon dioxide degassing from volcanic LIP degassing could have resulted in more than 90 percent global deep-ocean anoxia. Later on, when anoxia became widespread, the production of
nitrous oxide, a greenhouse gas about 265 times more potent than carbon dioxide, drastically increased because of elevated nitrification and denitrification rates. This powerful positive feedback mechanism is what may have enabled extremely hot temperatures to persist in spite of the supercharged organic carbon burial associated with anoxic events. This cooling event was insufficient at completely stopping the rise in global temperatures. This
negative feedback was ultimately overridden, as global temperatures continued to shoot up in sync with continued volcanic release of carbon dioxide following the Plenus Cool Event, although this theory has been criticised and the warming after the Plenus Cool Event attributed to decreased silicate weathering instead.
Ocean acidification Within the oceans, the emission of SO2, H2S, CO2, and
halogens would have increased the acidity of the water, causing the dissolution of carbonate, and a further release of carbon dioxide. Evidence of ocean acidification can be gleaned from δ44/40Ca increases coeval with the extinction event, as well as coccolith malformation and dwarfism. Lithologies characterised by low calcium carbonate concentrations predominated during intervals of carbonate compensation depth shoaling. Ocean acidification was exacerbated by a positive feedback loop of increased heterotrophic respiration in highly biologically productive waters, elevating seawater concentrations of carbon dioxide and further decreasing pH.
Anoxia and euxinia When the volcanic activity declined, this run-away
greenhouse effect would have likely been put into reverse. The increased CO2 content of the oceans could have increased organic productivity in the ocean surface waters. The consumption of this newly abundant organic life by
aerobic bacteria would produce anoxia and
mass extinction. The global environmental disturbance that resulted in these conditions increased atmospheric and oceanic temperatures. Extreme hothouse conditions encouraged
ocean stratification. Boundary sediments show an enrichment of trace elements, and contain elevated
δ13C values. The positive δ13C excursion found at the Cenomanian-Turonian boundary is one of the main carbon isotope events of the Mesozoic. It represents one of the largest disturbances in the global carbon cycle from the past 110 million years. This δ13C excursion indicates a significant increase in the burial rate of organic carbon, indicating the widespread deposition and preservation of organic carbon-rich sediments and that the ocean was depleted of oxygen at the time. Depletion of
manganese in sediments corresponding to OAE2 provides additional strong evidence of severe bottom water oxygen depletion. An increase in the abundance of the planktonic foraminifer
Heterohelix provides further evidence still of anoxia. The proto-North Atlantic in particular was a hotbed of carbon burial during OAE2 as it was in later, less severe anoxic events. Though anoxia was prevalent throughout the interval, there were transient periods of reoxygenation during OAE2. Sulphate reduction increased during OAE2, causing
euxinia, a type of anoxia defined by sulphate reduction and hydrogen sulfide production, to occur during OAE2, as revealed by negative δ53Cr excursions, positive δ98Mo excursions, a drawdown of seawater
molybdenum, and molecular biomarkers of
green sulfur bacteria. Although euxinia was not uncommon in the latter part of the Cenomanian, it only expanded into the photic zone during OAE2 itself. OAE2 began on the southern margins of the proto-North Atlantic, from where anoxia spread across the rest of the proto-North Atlantic and then into the Western Interior Seaway (WIS) and the epicontinental seas of the Western Tethys. Anoxic waters spread rapidly throughout the WIS due to marine transgression and a powerful cyclonic circulation resulting from an imbalance between precipitation in the north and evaporation in the south. Anoxia was especially intense in the eastern North Sea, evidenced by its very positive δ13C values. Thanks to persistent upwelling, some marine regions, such as the South Atlantic, were able to remain partially oxygenated at least intermittently. Indeed, redox states of oceans vary geographically, bathymetrically and temporally during OAE2.
Milankovitch cycles It has been hypothesised that the Cenomanian-Turonian boundary event occurred during a period of very low variability in Earth's insolation, which has been theorised to be the result of coincident nodes in all orbital parameters. Barring chaotic perturbations in Earth's and Mars' orbits, the simultaneous occurrence of nodes of
orbital eccentricity,
axial precession, and
obliquity on Earth occurs approximately every 2.45 million years. The MCE took place approximately 2.4 million years before the Cenomanian-Turonian oceanic anoxic event, roughly at the time when an anoxic event would be expected to occur given such a cycle. Geochemical evidence from a sediment core in the
Tarfaya Basin is indicative of the main positive carbon isotope excursion occurring during a prolonged eccentricity minimum. Carbon isotope shifts smaller in scale observed in this core likely reflected variability in obliquity. Ocean Drilling Program Site 1138 in the
Kerguelen Plateau yields evidence of a 20,000 to 70,000 year periodicity in changes in sedimentation, suggesting that either obliquity or precession governed the large-scale burial of organic carbon. Within the OAE2 positive δ13C excursion, short eccentricity scale carbon isotope variability is documented in a significantly expanded OAE2 interval from southern Tibet;
Enhanced phosphorus recycling The phosphorus retention ability of seafloor sediments declined during OAE2, revealed by a decline in reactive phosphorus species within OAE2 sediments. The mineralisation of seafloor phosphorus into apatite was inhibited by the significantly lower pH of seawater and much warmer temperatures during the Cenomanian and Turonian compared to the present day, which meant that significantly more phosphorus was recycled back into ocean water after being deposited on the sea floor during this time. This would have intensified a positive feedback loop in which phosphorus is recycled faster into anoxic seawater compared to oxygen-rich water, which in turn fertilises the water, causes increased eutrophication, and further depletes the seawater of oxygen. The influx of volcanically erupted and chemically weathered sulfate into the ocean also inhibited phosphorus burial by increasing hydrogen sulfide production, which hinders the burial of phosphorus through sorption to iron oxyhydroxide phases. OAE2 may have occurred during a peak in a 5-6 Myr cycle governing phosphorus availability; at this and other peaks in this oscillation, an increase in chemical weathering would have increased the marine phosphorus inventory and sparked a positive feedback loop of increasing productivity, anoxia, and phosphorus recycling that was only ended by a negative feedback of increased atmospheric oxygenation and wildfire activity that decreased chemical weathering, a feedback which operated on a much longer timescale. Enhanced phosphorus recycling would have resulted in an abundance of
nitrogen fixing bacteria, increasing the availability of yet another limiting nutrient and supercharging primary productivity through
nitrogen fixation. The ratio of bioavailable nitrogen to bioavailable phosphorus, which is 16:1 in the present, fell precipitously as the ocean transitioned from being oxic and nitrate-dominated to anoxic and ammonium-dominated. A potent feedback loop of nitrogen fixation, productivity, deoxygenation, nitrogen removal, and phosphorus recycling was created. Bacterial hopanoids indicate populations of nitrogen fixing cyanobacteria were high during OAE2, providing a rich supply of nitrates and nitrites. Negative
δ15N values reveal the dominance of ammonium through regenerative nutrient loops in the proto-North Atlantic.
Decreased sulfide oxidation In the present day, sulfidic waters are generally prevented from spreading throughout the water column by the oxidation of sulfide with nitrate. However, during OAE2, the inventory of seawater nitrate was lower, meaning that chemolithoautotrophic oxidation of sulfides with nitrates was inefficient at preventing the spread of euxinia.
Sea level rise A marine transgression in the latest Cenomanian resulted in an increase in average water depth, causing seawater to become less eutrophic in shallow, epicontinental seas. Turnovers in marine biota in such epicontinental seas have been suggested to be driven more so by changes in water depth rather than anoxia. Sea level rise also contributed to anoxia by transporting terrestrial plant matter from inundated lands seaward, providing an abundant source of sustenance for eutrophicating microorganisms. == Geological effects ==