Dael Sassoon, Nathalie Combourieu-Nebout, Odile Peyron, Adele Bertini, Francesco Toti, Vincent Lebreton, Marie-Hélène Moncel
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In this study, a multi-method approach is used to produce climatic reconstructions for MIS 19, 11, 5 and 1, using pollen data derived from a single long marine core from ODP Site 976. This represents the first study which attempts to use pollen-based climatic reconstructions to compare MIS 1 with its analogues, representing a necessary contribution to the debate with a focus on the relationships between vegetation and climate in the southwestern Mediterranean. Three methods of quantitative climate reconstruction have been adopted: the more widely used methods Modern Analogues Technique (MAT) and Weighted Average Partial Least Squares regression (WA-PLS), and a more recent machine-learning method known as Boosted Regression Trees (BRT). The reconstructions show consistent changes in temperature and precipitation during MIS 19, 11, 5 and 1, which correlate well with climatic changes observed in other regional and global proxies, and highlight distinct climatic characteristics of each interglacial period in the southwestern Mediterranean. MIS 19 exhibits high variability and colder temperatures compared to subsequent interglacials and the MIS 1. Conversely, MIS 11 displays warmer temperatures and greater stability, which makes it a useful analogue to understand prolonged interglacials, crucial considering the anthropogenic impacts on the duration of warm climate during the Holocene. MIS 5 exhibits overall warmer conditions, and its higher temperature coupled with fluctuations in solar forcing makes it a less suitable MIS 1 analogue. 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引用次数: 0
摘要
摘要由于类似的太阳强迫模式、温室气体浓度和海平面,更新世间冰期,特别是 MIS 19、11 和 5 被认为是 MIS 1 的类似期。关于哪个时期是最合适的类比期,人们一直争论不休,至今尚未达成共识,不过从最近的研究中可以看出,这些时期的区域气候变化很大。限制我们了解这些潜在类似期的因素之一是,很少有长序列能够高分辨率地涵盖这些间冰期的整个持续时间。在本研究中,利用从 ODP 976 号站点获取的单个长海洋岩芯的花粉数据,采用多种方法重建了 MIS 19、11、5 和 1 的气候。这是首次尝试使用基于花粉的气候重建来比较 MIS 1 与其类似物的研究,是对以地中海西南部植被与气候关系为重点的讨论的必要贡献。研究采用了三种定量气候重建方法:应用较广的现代类比技术(MAT)和加权平均最小二乘法回归(WA-PLS),以及一种较新的机器学习方法,即增强回归树(BRT)。重建结果表明,在 MIS 19、11、5 和 1 期间,气温和降水量发生了一致的变化,这与其他地区和全球代用指标观测到的气候变化密切相关,并凸显了地中海西南部每个间冰期的独特气候特征。与随后的间冰期和间冰期 1 相比,间冰期 19 表现出较高的可变性和较低的温度;相反,间冰期 11 表现出较高的温度和较强的稳定性,这使其成为了解长期间冰期的一个有用类比,考虑到人类活动对全新世温暖气候持续时间的影响,这一点至关重要。MIS 5 显示出总体较暖的条件,其较高的温度加上太阳强迫的波动,使其不太适合作为 MIS 1 的类似物。虽然过去的间冰期不能直接预测全新世的未来,但它们提供了地球对各种强迫因素反应的重要见解,是了解地中海对全球变化敏感性的重要基准。
Pollen-based climatic reconstructions for the interglacial analogues of MIS 1 (MIS 19, 11 and 5) in the Southwestern Mediterranean: insights from ODP Site 976
Abstract. Pleistocene interglacials, specifically MIS 19, 11 and 5, have been suggested as analogues of MIS 1 due to similar solar forcing patterns, greenhouse gas concentrations and sea levels. There has been substantial debate regarding which of these is the most suitable analogue and so far there has been no consensus, although what really emerges from recent work is the high variation in regional climate during these periods. One of the limiting factors in our understanding of these potential analogues is the fact that very few long-sequences cover the entire duration of these interglacials at high resolution. In this study, a multi-method approach is used to produce climatic reconstructions for MIS 19, 11, 5 and 1, using pollen data derived from a single long marine core from ODP Site 976. This represents the first study which attempts to use pollen-based climatic reconstructions to compare MIS 1 with its analogues, representing a necessary contribution to the debate with a focus on the relationships between vegetation and climate in the southwestern Mediterranean. Three methods of quantitative climate reconstruction have been adopted: the more widely used methods Modern Analogues Technique (MAT) and Weighted Average Partial Least Squares regression (WA-PLS), and a more recent machine-learning method known as Boosted Regression Trees (BRT). The reconstructions show consistent changes in temperature and precipitation during MIS 19, 11, 5 and 1, which correlate well with climatic changes observed in other regional and global proxies, and highlight distinct climatic characteristics of each interglacial period in the southwestern Mediterranean. MIS 19 exhibits high variability and colder temperatures compared to subsequent interglacials and the MIS 1. Conversely, MIS 11 displays warmer temperatures and greater stability, which makes it a useful analogue to understand prolonged interglacials, crucial considering the anthropogenic impacts on the duration of warm climate during the Holocene. MIS 5 exhibits overall warmer conditions, and its higher temperature coupled with fluctuations in solar forcing makes it a less suitable MIS 1 analogue. Although past interglacials do not offer direct predictions for the Holocene's future, they provide essential insights into Earth's responses to various forcing factors, serving as crucial benchmarks for understanding the Mediterranean's sensitivity to global changes.
期刊介绍:
Climate of the Past (CP) is a not-for-profit international scientific journal dedicated to the publication and discussion of research articles, short communications, and review papers on the climate history of the Earth. CP covers all temporal scales of climate change and variability, from geological time through to multidecadal studies of the last century. Studies focusing mainly on present and future climate are not within scope.
The main subject areas are the following:
reconstructions of past climate based on instrumental and historical data as well as proxy data from marine and terrestrial (including ice) archives;
development and validation of new proxies, improvements of the precision and accuracy of proxy data;
theoretical and empirical studies of processes in and feedback mechanisms between all climate system components in relation to past climate change on all space scales and timescales;
simulation of past climate and model-based interpretation of palaeoclimate data for a better understanding of present and future climate variability and climate change.