Abstract
The Western Pacific Warm Pool (WP), with the highest sea surface temperature (SST) in the world, has strong impacts on the drought variations in Eurasia. However, since the little ice age (1250–1850, LIA), the co-climatic drought pattern due to WP warming in Eurasia remains unclear. This is a long-term warming background for the current warming period (CWP). In this paper, we use both instrumental data and 1625 tree-ring width records from Eurasia to investigate the drought patterns in both modern and historical periods. This study revealed two seesaw precipitation patterns, namely the Central Asia–Mongolia (CAMO) and Northern Europe–Southern Europe (NESE) patterns. When the Western Pacific Warm Pool sea surface temperature (WPSST) is high, precipitation increases in Central Asia and Northern Europe, and decreases in Mongolia and southern Europe. When the positive (negative) phase event of the El Niño–Southern Oscillation (ENSO) occurs, the WPSST is reduced (increased), and the decreases (increases) of precipitation in Central Asia and Northern Europe and the increases (decreases) in precipitation in Mongolia and southern Europe are more obvious. The CAMO dipole has been strengthened since the LIA. The CAMO dipole is positively correlated with solar radiation and Northern Hemisphere temperature, and negatively correlated with Pacific decadal oscillations (PDO).
Highlights
Global warming has changed the water cycle, such as increasing the frequency and intensity of global droughts and floods [1]
With the precipitation in Central Asia positively correlated with the Warm Pool sea surface temperature (WPSST), and precipitation in Mongolia negatively correlated with the WPSST [30,31]
This was defined as the Central Asia–Mongolia (CAMO) dipole pattern
Summary
Global warming has changed the water cycle, such as increasing the frequency and intensity of global droughts and floods [1]. Assessing drought trends in the context of global warming is important, because the economic costs of drought far outweigh the costs of other natural disasters in the context of global warming [2]. A great deal of research has been done to investigate the temporal and spatial variations of drought and the relationships between variations in different regions. Some studies have shown that the Western Pacific Warm Pool sea surface temperature (WPSST) affects the drought patterns in Quaternary 2020, 3, 16; doi:10.3390/quat3020016 www.mdpi.com/journal/quaternary. The Western Pacific Warm Pool (WP) was covered by a thick surface of warm water, which is an important source of global heat and water [6]. The hydrological changes in WP are closely related to the high latitude climate change via modulating large-scale circulation systems [3,7,8,9]
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