The Middle Eocene Climatic Optimum (MECO), also called the Middle Eocene Thermal Maximum (METM),[1] was a period of very warm climate that occurred during the
Bartonian, from around 40.5 to 40.0
Ma.[2] It marked a notable reversal of the overall trend of global cooling that characterised the
Middle and
Late Eocene.[1]
Duration
The length of time that the MECO spanned is disputed, although it is known to have lasted from around 40.5 to 40.0 Ma. Depending on location and methodology, the event's duration has been variously estimated at 300,[3] 500,[2] 600,[4] and 750
kyr.[5]
Climate
The MECO was globally synchronous and observed in both marine and terrestrial sequences.[6] The
global mean surface temperature during the MECO was about 23.1 °C.[1] In the
Tethys Ocean,
sea surface temperatures (SSTs) have been estimated at 32-36 °C.[7] Water temperatures off what is now
Liguria rose by about 4-6 °C,[8] while the seas off southwestern
Balkanatolia warmed by 2-5 °C.[9] The northwestern Atlantic experienced a 3 °C increase in upper ocean temperatures.[10] In the southwestern
Pacific, SSTs rose from an average of about 22 °C to 28 °C.[11] Deep ocean temperatures were about 9 °C at the peak of the MECO.[12] On the shallow shelf around Seymour Island, temperatures warmed by ~5 °C.[13] The
North American continental interior warmed more pronouncedly, by 9 °C from 23 °C ± 3 °C to 32 °C ± 3 °C at the peak of the MECO, followed by a decline of 11 °C after the MECO.[14]
In
Western North America,
lakes became markedly less
saline.[15] Continental Asia was once thought to have experienced intense
aridification during the MECO, though more recent
research has shown that this took place after the MECO, when global average temperatures resumed dropping.[16]
A decline in seawater oxygen content occurred during the MECO in the Tethys Ocean.[21][17][7] Dysoxic conditions in the Tethys lasted for about 400-500 kyr according to geochemical study of the Alano site in northeastern Italy.[22] Evidence from the
Southern Ocean indicates deep water deoxygenation developed in this marine region too.[23] Organic carbon burial rates skyrocketed in these oxygen-poor waters, which may have acted as a negative feedback that helped restore global temperatures to their pre-MECO state after the warming ended.[24] However, deoxygenation was not globally ubiquitous; South Atlantic sites such as South Atlantic Ocean Drilling Program Site 702 show no evidence of any shift towards dysoxic conditions.[3]
There is
evidence of
ocean acidification occurring during the MECO in the form of major declines in carbonate accumulation throughout the ocean at depths of greater than three kilometres.[2] Acidification affected the entire water column, extending as far as the
abyssal zone.[25]
Causes
The MECO was marked by a notable rise in
atmospheric carbon dioxide concentrations.[2] At their peak,
pCO2 values may have reached as high as 4,000 ppm.[26] One possible cause of this rise in pCO2 was the collision of
India with
Eurasia and formation of the
Himalayas that was occurring at this time, which would have metamorphically liberated large quantities of the greenhouse gas, although the timing of metamorphic carbon release is poorly resolved. Enhanced rates of seafloor spreading and metamorphic decarbonation reactions around the region between
Australia and
Antarctica, combined with increased
volcanic activity in this region, may also have been a source of the carbon injection into the atmosphere.[4] Yet another
hypothesis implicates increased continental arc volcanism in what are now Azerbaijan and Iran for this surge in atmospheric greenhouse gas levels.[27]
Diminished negative feedback of
silicate weathering may have occurred around the time of the MECO's onset and allowed volcanically released carbon dioxide to persist in the atmosphere for longer. This may have come about as a result of continental rocks having become less weatherable during the very warm Early Eocene and Early Middle Eocene; by the time of the MECO, few areas of silicate rock potent enough to absorb significant amounts of carbon dioxide would have remained.[28] The MECO warmth may have been sustained through a further inhibition of silicate weathering following the onset of warming via enhanced
clay formation.[29]
Milankovitch cycles have been suggested to have played a role in triggering MECO warmth. The MECO coincided with a minimum in the 2.4 Myr eccentricity cycle that occurred around 40.2 Ma.[30] This 2.4 Myr eccentricity minimum coincided with a minimum in the 400 kyr eccentricity cycle; the simultaneous occurrence of these eccentricity minima likely fomented the conditions enabling the MECO's persistent global warmth.[31]
Biotic effects
Planktonic foraminifera underwent a major biotic turnover; acarinids were greatly reduced in
diversity and morozovellids went extinct.[32] The range of the planktonic foraminifer Orbulinoides beckmanni, a
species well adapted to warm waters, expanded to higher latitudes during the MECO.[5][33] Benthic foraminifera exhibited a decline due to enhanced respiration of pelagic heterotrophs, limiting the amount of organic matter making its way to the ocean depths.[34][35] Large benthic foraminifera, however, thrived.[36] The MECO coincided with the replacement of
lamniformelasmobranchs with
carcharhinids in the medium to large predator guild.[37]
In North America, the MECO marked the high point of the Middle-Late Eocene mammalian assemblage.[38] MECO warmth catalysed the
faunal turnover leading to the rise of crown-group
carnivorans to prominence in the
continent's terrestrial ecosystems.[39][40]
In Balkanatolia, lower montane forests and warm, humid lowland rainforests were the dominant biomes in what is now the middle Black Sea region of northern Anatolia.[41]
The
plant diversity of
Patagonia increased by 40% during the MECO, largely due to the southward migration of
neotropical plants that mixed with the established temperate Gondwanan flora.[42] Neotropical lineages that today only occupy the tropics reached the southernmost end of South America.[43] Nourished by abundant carbon dioxide and a favourable temperature, this highly diverse
flora reverted to pre-MECO levels of biodiversity after the hothouse concluded.[42]
Coastal southeastern Australia was dominated by mesothermal rainforests, although whether or not this flora was already present before the MECO remains up for debate.[44]