Distinct response of Asian summer monsoon circulation and precipitation to orbital forcing during six Heinrich events

IF 3.2 1区 地球科学 Q1 GEOGRAPHY, PHYSICAL
Ming-Qiang Liang , Qiuzhen Yin , Yong Sun , Chao Zhang , André Berger , Anqi Lyu , Wei Liu , Zhipeng Wu
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引用次数: 0

Abstract

Climatic fingerprint of Heinrich (H) events was characterized by widespread megadroughts over the Asian summer monsoon (ASM) region accompanied by systemic weakening of the ASM. However, recent studies of hydroclimate proxies suggest huge spatial discrepancies in precipitation over the ASM region during some H events, characterized by increased precipitation in the Yangtze River Valley contrasting with the prevalent megadroughts across the whole ASM region. The mechanism responsible for the spatial discrepancies in precipitation and the relationship between local precipitation and the ASM intensity remain elusive. In this study, we investigate the response of the ASM circulation and precipitation to orbital forcing during six H events based on simulations with a coupled atmosphere-ocean general circulation model. The results show that changes in insolation alone can induce spatial discrepancies in precipitation over the ASM region during the H events. During the H1, 3, 4, 5, 6 events, the amplification of the land-sea pressure contrast in response to a positive interhemispheric insolation gradient (30°N-30°S) during boreal summer intensifies moisture transport from the adjacent oceans to the ASM region. The ensuing moisture divergence, combined with anomalous downdrafts, results in decreased precipitation in the South Asian Summer Monsoon (SASM) region, but converse scenario for the East Asian Summer Monsoon (EASM) region. During the H2 event, the increased precipitation across the Yangtze River Valley sharply contrasts the widespread drought over the ASM region, attributing to an anticyclone anomaly over the subtropical Western North Pacific and a cyclone anomaly over Japan and Korea. Moisture budget analysis shows that the dynamic effect, especially the vertical term, rather than the thermodynamic effect, is the dominant control of precipitation changes over the ASM region. Our results also suggest that despite the synchronous variation in the strength of the EASM and SASM in response to orbital forcing, the EASM should not be regarded as an eastward and northward extension of the SASM. Furthermore, our model simulates a weak correlation between the monsoon intensity and precipitation in the SASM region in response to orbital forcing, calling for caution in employing precipitation to reconstruct SASM intensity on orbital time scale.

六次海因里希事件期间亚洲夏季季风环流和降水对轨道强迫的不同反应
海因里希(H)事件的气候特征是亚洲夏季季风(ASM)地区大范围的特大干旱,同时伴有系统性的亚洲夏季季风减弱。然而,最近的水文气候代用指标研究表明,在某些海因里希事件期间,亚洲夏季季风区降水量存在巨大的空间差异,其特点是长江流域降水量增加,与整个亚洲夏季季风区普遍的大干旱形成鲜明对比。造成降水空间差异的机制以及局地降水与 ASM 强度之间的关系仍不明确。在本研究中,我们基于大气-海洋耦合大气环流模式的模拟,研究了六次H事件期间ASM环流和降水对轨道强迫的响应。结果表明,在 H 事件期间,仅日照变化就能引起 ASM 区域降水的空间差异。在 H1、3、4、5、6 事件期间,由于北半球夏季出现正的半球间日照梯度(北纬 30°-南纬 30°),海陆气压对比扩大,加剧了从邻近海洋向 ASM 地区的水汽输送。随之而来的水汽辐散与异常下沉气流相结合,导致南亚夏季季风区降水量减少,而东亚夏季季风区降水量则相反。在 H2 事件期间,长江流域降水增加,与夏季季候风地区的大范围干旱形成鲜明对比,这归因于副热带西北太平洋上空的反气旋异常和日本及韩国上空的气旋异常。水汽预算分析表明,动态效应,特别是垂直项,而不是热力学效应,是控制 ASM 地区降水变化的主导因素。我们的结果还表明,尽管 EASM 和 SASM 的强度随轨道强迫而同步变化,但不应将 EASM 视为 SASM 向东和向北的延伸。此外,我们的模式模拟了 SASM 区域季风强度与降水量在轨道强迫作用下的微弱相关性,因此在利用降水量重建轨道时间尺度上的 SASM 强度时需要谨慎。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Quaternary Science Reviews
Quaternary Science Reviews 地学-地球科学综合
CiteScore
7.50
自引率
15.00%
发文量
388
审稿时长
3 months
期刊介绍: Quaternary Science Reviews caters for all aspects of Quaternary science, and includes, for example, geology, geomorphology, geography, archaeology, soil science, palaeobotany, palaeontology, palaeoclimatology and the full range of applicable dating methods. The dividing line between what constitutes the review paper and one which contains new original data is not easy to establish, so QSR also publishes papers with new data especially if these perform a review function. All the Quaternary sciences are changing rapidly and subject to re-evaluation as the pace of discovery quickens; thus the diverse but comprehensive role of Quaternary Science Reviews keeps readers abreast of the wider issues relating to new developments in the field.
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