Abstract
Abstract. The middle Miocene climate transition (MMCT) was a phase of global cooling possibly linked to decreasing levels of atmospheric CO2. The MMCT coincided with the European Mammal Faunal Zone MN6. From this time, important biogeographic links between Anatolia and eastern Africa include the hominid Kenyapithecus. Vertebrate fossils suggested mixed open and forested landscapes under (sub)tropical seasonal climates for Anatolia. Here, we infer the palaeoclimate during the MMCT and the succeeding cooling phase for a middle Miocene (14.8–13.2 Ma) intramontane basin in southwestern Anatolia using three palaeobotanical proxies: (i) Köppen signatures based on the nearest living-relative principle; (ii) leaf physiognomy analysed with the Climate Leaf Analysis Multivariate Program (CLAMP); (iii) genus-level biogeographic affinities of fossil flora with modern regions. The three proxies reject tropical and hot subtropical climates for the MMCT of southwestern Anatolia and instead infer mild warm temperate C climates. Köppen signatures reject summer-dry Cs climates but cannot discriminate between fully humid Cf and winter-dry Cw; CLAMP reconstructs Cf climate based on the low X3.wet∕X3.dry ratio. Additionally, we assess whether the palaeobotanical record resolves transitions from the warm Miocene Climatic Optimum (MCO, 16.8–14.7 Ma) to the MMCT (14.7–13.9 Ma), and a more pronounced cooling at 13.9–13.8 Ma, as reconstructed from benthic stable isotope data. For southwestern Anatolia, we find that arboreal taxa predominate in MCO flora (MN5), whereas in MMCT flora (MN6) abundances of arboreal and non-arboreal elements strongly fluctuate, indicating higher structural complexity of the vegetation. Our data show a distinct pollen zone between MN6 and MN7+8 dominated by herbaceous taxa. The boundary between MN6 and MN7+8, roughly corresponding to a first abrupt cooling at 13.9–13.8 Ma, might be associated with this herb-rich pollen zone.
Highlights
The middle Miocene (15.97–11.63 Ma, ICS-chart 2017/02, Cohen, 2013) is characterized by a warm phase lasting until ca. 15 Ma that was followed by a gradual cooling and the restoration of a major Antarctic ice sheet and the first northern hemispheric glaciations (Holbourn et al, 2014)
We decided against applying quantitative nearest living relative (NLR) methods and determined Köppen signatures for fossil taxa using information from all extant species of a genus used as NLR to avoid bias from undetected niche shifts
We showed that the palaeobotanical record resolves transitions from the warm Miocene Climatic Optimum (MCO) (16.8– 14.7 Ma) to the middle Miocene climate transition (MMCT) (14.7–13.9 Ma) and a more pronounced cooling at 13.9–13.8 Ma, mainly expressed in the changing and fluctuating ratios between arboreal pollen (AP) and non-arboreal pollen (NAP) taxa
Summary
The middle Miocene (15.97–11.63 Ma, ICS-chart 2017/02, Cohen, 2013) is characterized by a warm phase lasting until ca. 15 Ma that was followed by a gradual cooling and the restoration of a major Antarctic ice sheet and the first northern hemispheric glaciations (Holbourn et al, 2014). During the middle Miocene climate transition (MMCT) at 14.7 to 13.8 Ma, a drop in sea surface temperatures of 6–7 ◦C occurred (Shevenell et al, 2004). Different proxies to reconstruct atmospheric CO2 levels for the Miocene Climatic Optimum (MCO), MMCT, and the succeeding more pronounced cooling do not concur (Beerling and Royer, 2011). Stable isotope data from phytoplankton infer stable CO2 levels for the Neogene, with minor fluctuations (MCO, 227–327 ppm; MMCT, 265– 300 ppm; see Table S1 of Beerling and Royer, 2011), while stomata densities from fossil leaves suggest a pronounced drop in CO2 after the MCO (see Table S1 of Beerling and Royer, 2011)
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