High‐Latitude, Indian Ocean, and Orbital Influences on Eastern African Hydroclimate Across the Plio‐Pleistocene Boundary

Paleoceanography and Paleoclimatology Pub Date : 2023-11-30 DOI:10.1029/2023PA004671

B. Mitsunaga, R. Lupien, Samantha Ouertani, Brandon Stubbs, A. Deino, J. Kingston, M. Stockhecke, Erik T. Brown, James M. Russell

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Abstract

Terrestrial‐marine dust fluxes, pedogenic carbonate δ13C values, and various paleovegetation proxies suggest that Africa experienced gradual cooling and drying across the Pliocene‐Pleistocene (Plio‐Pleistocene) boundary (2.58 million years ago [Ma]). However, the timing, magnitude, resolution, and relative influences of orbitally‐driven changes in high latitude glaciations and low latitude insolation differ by region and proxy. To disentangle these forcings and investigate equatorial eastern African climate across the Plio‐Pleistocene boundary, we generated a high‐resolution (∼3,000‐year) data set of compound‐specific n‐alkane leaf wax δ2H values—a robust proxy for atmospheric circulation and precipitation amount—from the HSPDP‐BTB13‐1A core, which spans a ∼3.3–2.6 Ma sequence in the Baringo‐Tugen Hills‐Barsemoi Basin of central Kenya. In combination with the physical sedimentology, our data indicate that precipitation varied strongly with orbital obliquity, not precession, during the late Pliocene, perhaps imparted by variations in the cross‐equatorial insolation gradient. We also observe a marked shift toward wetter conditions beginning ∼3 Ma that corresponds with global cooling, drying in western Australia, and a steepening of the west‐east zonal Indian Ocean (IO) sea surface temperature (SST) gradient. We propose that northward migration of the Subtropical Front reduced Agulhas current leakage, warming the western IO and causing changes in the IO zonal SST gradient at 3 Ma, a process that has been observed in the latest Pleistocene‐Holocene but not over longer timescales. Thus, the late Cenozoic moisture history of eastern Africa is driven by a complex mixture of low‐latitude insolation, the IO SST gradient, and teleconnections to distal high‐latitude cooling.

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高纬度、印度洋和轨道对整个上新世-更新世边界东非水文气候的影响

陆地-海洋尘埃通量、成泥碳酸盐δ13C 值以及各种古植被代用指标表明，非洲在整个上新世-早更新世（Pliocene-Pleistocene）边界（258 万年前 [Ma]）经历了逐渐变冷和变干的过程。然而，高纬度冰川和低纬度日照的轨道驱动变化的时间、幅度、分辨率和相对影响因地区和代理变量而异。为了厘清这些作用力并研究整个上新世-更新世边界的赤道东非气候，我们从肯尼亚中部巴林戈-图根山-巴斯莫伊盆地的 HSPDP-BTB13-1A 岩心中生成了一组高分辨率（∼3,000 年）的化合物特异性正构烷烃叶蜡 δ2H 值--大气环流和降水量的可靠代用指标，该岩心横跨肯尼亚中部巴林戈-图根山-巴斯莫伊盆地的 ∼3.3-2.6 Ma 序列。结合物理沉积学，我们的数据表明，在上新世晚期，降水量随轨道斜度（而非躔度）的变化而强烈变化，这可能是由跨赤道日照梯度的变化所引起的。我们还观察到，从公元前 3 年开始，气候明显趋于湿润，这与全球变冷、澳大利亚西部变干以及印度洋西-东带海面温度梯度变陡相呼应。我们认为，亚热带前线的北移减少了阿古哈斯洋流的泄漏，使印度洋西部变暖，并导致印度洋地带性海面温度梯度在 3 Ma 发生变化，这一过程在更新世-全新世时期已经被观测到，但在更长的时间尺度上却没有被观测到。因此，非洲东部晚新生代的水汽历史是由低纬度日照、IO 海温梯度以及与远端高纬度降温的远距离联系等复杂因素共同驱动的。

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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Paleoceanography and Paleoclimatology

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