Research School of Earth Sciences, The Australian National University, Canberra, Australian Capital Territory, Australia.
ARC Centre of Excellence for Climate Extremes, The Australian National University, Canberra, Australian Capital Territory, Australia.
Nature. 2020 Mar;579(7799):385-392. doi: 10.1038/s41586-020-2084-4. Epub 2020 Mar 9.
The Indian Ocean Dipole (IOD) affects climate and rainfall across the world, and most severely in nations surrounding the Indian Ocean. The frequency and intensity of positive IOD events increased during the twentieth century and may continue to intensify in a warming world. However, confidence in predictions of future IOD change is limited by known biases in IOD models and the lack of information on natural IOD variability before anthropogenic climate change. Here we use precisely dated and highly resolved coral records from the eastern equatorial Indian Ocean, where the signature of IOD variability is strong and unambiguous, to produce a semi-continuous reconstruction of IOD variability that covers five centuries of the last millennium. Our reconstruction demonstrates that extreme positive IOD events were rare before 1960. However, the most extreme event on record (1997) is not unprecedented, because at least one event that was approximately 27 to 42 per cent larger occurred naturally during the seventeenth century. We further show that a persistent, tight coupling existed between the variability of the IOD and the El Niño/Southern Oscillation during the last millennium. Indo-Pacific coupling was characterized by weak interannual variability before approximately 1590, which probably altered teleconnection patterns, and by anomalously strong variability during the seventeenth century, which was associated with societal upheaval in tropical Asia. A tendency towards clustering of positive IOD events is evident in our reconstruction, which-together with the identification of extreme IOD variability and persistent tropical Indo-Pacific climate coupling-may have implications for improving seasonal and decadal predictions and managing the climate risks of future IOD variability.
印度洋偶极子(IOD)会影响全球的气候和降雨,对印度洋周边国家的影响尤为严重。IOD 的正位相事件在 20 世纪期间变得更加频繁和强烈,并且在全球变暖的情况下可能会继续加剧。然而,IOD 未来变化的预测受到已知的 IOD 模型偏差和人为气候变化之前关于自然 IOD 变率的信息缺乏的限制。在这里,我们使用来自东赤道印度洋的精确定年和高分辨率珊瑚记录,IOD 变率的特征在那里强烈而明确,制作了过去一千年中五个世纪的 IOD 变率的半连续重建。我们的重建表明,1960 年之前,极端正位相 IOD 事件很少发生。然而,记录中最极端的事件(1997 年)并非史无前例,因为在 17 世纪期间自然发生的事件至少有一次大约大 27%至 42%。我们进一步表明,IOD 的变化与上千年的厄尔尼诺/南方涛动之间存在持久而紧密的耦合。在大约 1590 年之前,IOD 和热带太平洋之间的年际变率较弱,这可能改变了遥相关模式,而在 17 世纪期间的变率异常强烈,这与热带亚洲的社会动荡有关。在我们的重建中,IOD 正位相事件的聚类趋势明显,这一点——加上极端 IOD 变率和持久的热带印度洋-太平洋气候耦合的识别——可能对提高季节和十年预测以及管理未来 IOD 变率的气候风险具有重要意义。
