Cooling-driven climate change at 12–11 Ma: Multiproxy records from a long fluviolacustrine sequence at Guyuan, Ningxia, China

To explore the evolution of climate through the Miocene, especially during the Middle Miocene climate transition, multiproxy continental records were analyzed by susceptibility (SUS), lightness (L), total inorganic carbon (TIC) and total organic carbon (TOC) content from the 2900-m-thick fluviolacustrine sediment sequence at Guyuan, Ningxia, China and compared with the redness (a) and the pollen humidity indices from the same section. The published Miocene records of sedimentation rate, sediment grain size, biota turnover, and palaeoproductivity from other regions were also compiled and compared. Results show that multiproxies of the Sikouzi section have changed substantially since 12–11 Ma ago. SUS, L and TIC have increased while a, TOC and the pollen humidity index decreased, all implying that the palaeoclimate in the study area has got cooler and drier since that time.This climate change also left imprints in many other regions, probably resulting from global cooling and the development of the East Antarctic Ice Sheet since about 14 Ma. Several positive feedback mechanisms are proposed to have effectively modulated and magnified the Mid-Miocene global cooling, including vegetation change, greenhouse gas (atmospheric CO₂ and water vapor) fluctuations. They led to the strengthing of ocean and atmospheric circulation, significant lowering of sea level and increasing aridification over the globe, especially in middle-high latitudes. Since 12–11 Ma ago, a continuously cooler and drier climate may have caused the substantial intensification of physical weathering and exhumation on the earth's surface, the increased sediment accumulation rates on the land and in the sea, and the inception of productivity increase in the oceans. Nevertheless, when and where these mechanisms operated and how they were tied to each other remain ambiguous, deserving further investigation.     

A 20 Ma pollen record of East-Asian summer monsoon evolution from Guyuan, Ningxia, China

Pollen analysis was conducted on the fluviolacustrine sediments from the east side of the Liupan Mountains, a relatively monsoon-sensitive region, and provided for the first time a continuous evolutionary history of vegetation and climate in East China during the Neogene. The pollen record spanning the last 20 Ma indicates that the vegetation and thus East-Asian summer monsoon evolution can be divided into three stages: 20.13–14.25 Ma, 14.25–11.35 Ma and 11.35–0.08 Ma, in spite of general dominance of steppe throughout the Neogene. During the period 20.13–14.25 Ma, the pollen assemblage was characterized by high abundance of Artemisia and small amounts of temperate to subtropical deciduous broad-leafed trees such as Juglans, Carya, Quercus and Betula, suggesting that the East-Asian summer monsoon was generally strong. The interval from 14.25 to 11.35 Ma was marked by a significant decline in the East-Asian summer monsoon, as indicated by Artemisia gradually replaced by Humulus and halophytic Chenopodiaceae. Nitraria and Ephedra also reached high values in this period. Since 11.35 Ma ago, percentages of halophytes dominated by Chenopodiaceae and Tamaricaceae maintained a high mean value of about 40%, revealing a weak intensity of East-Asian summer monsoon. The general weakening of the monsoon circulation during the Neogene and the significant monsoon decline during the late Middle Miocene in particular might link with the global cooling trend probably through two mechanisms. Cooling and ice-sheet expansion over the polar region caused an increase in meridional temperature gradients leading to the southward retreat of the monsoon circulation. The global cooling may have also reduced the amount of water vapor held in the atmosphere, and led to both additional cooling and further weakening of the East-Asian summer monsoon. The cause for a short-lived resumption during the period 1.0–0.8 Ma is under investigation.