Dynamic interaction between lakes, climate, and vegetation across northern Africa during the mid-Holocene

IF 3.8 2区 地球科学 Q1 GEOSCIENCES, MULTIDISCIPLINARY
Nora Farina Specht, Martin Claussen, Thomas Kleinen
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引用次数: 0

Abstract

Abstract. During the early Holocene to mid-Holocene, about 11 500 to 5500 years ago, lakes expanded across the Sahel and Sahara in response to enhanced summer monsoon precipitation. To investigate the effect of these lakes on the West African summer monsoon, previous simulation studies prescribed mid-Holocene lakes from reconstructions. By prescribing mid-Holocene lakes, however, the terrestrial water balance is inconsistent with the size of the lakes. In order to close the terrestrial water cycle, we construct a dynamic endorheic lake (DEL) model and implement it into the atmosphere–land model ICON-JSBACH4. For the first time, this allows us to investigate the dynamic interaction between climate, lakes, and vegetation across northern Africa. Additionally, we investigate the effect of lake depth changes on mid-Holocene precipitation, a neglected aspect in previous simulation studies. A pre-industrial control simulation shows that the DEL model realistically simulates the lake extent across northern Africa. Only in the Ahnet and Chotts basins is the lake area slightly overestimated, which is likely related to the coarse resolution of the simulations. The mid-Holocene simulations reveal that both the lake expansion and the vegetation expansion cause a precipitation increase over northern Africa. The sum of these individual contributions to the precipitation is, however, larger than the combined effect that is generated when lake and vegetation dynamics interact. Thus, the lake–vegetation interaction causes a relative drying response across the entire Sahel. The main reason for this drying response is that the simulated vegetation expansion cools the land surface more strongly than the lake expansion, which is dominated by the expansion of Lake Chad. Accordingly, the surface temperature increases over the region of Lake Chad and causes local changes in the meridional surface-temperature gradient. These changes in the meridional surface-temperature gradient are associated with reduced inland moisture transport from the tropical Atlantic into the Sahel, which causes a drying response in the Sahel. An idealized mid-Holocene experiment shows that a similar drying response is induced when the depth of Lake Chad is decreased by about 1–5 m, without changing the horizontal lake area. By reducing the depth of Lake Chad, the heat storage capacity of the lake decreases, and the lake warms faster during the summer months. Thus, in the ICON-JSBACH4 model, the lake depth significantly influences the simulated surface temperature and the simulated meridional surface-temperature gradient between the simulated lakes and vegetation, thereby affecting mid-Holocene precipitation over northern Africa.
全新世中期整个非洲北部湖泊、气候和植被之间的动态相互作用
摘要在全新世早期至全新世中期,即距今约 11 500 至 5500 年前,萨赫勒和撒哈拉地区的湖泊因夏季季风降水增强而扩大。为了探究这些湖泊对西非夏季季风的影响,以往的模拟研究根据重建结果预设了全新世中期的湖泊。然而,由于预设了全新世中期的湖泊,陆地水量平衡与湖泊的大小并不一致。为了关闭陆地水循环,我们构建了一个动态内流体湖泊(DEL)模型,并将其应用于大气-陆地模型 ICON-JSBACH4。这使我们首次研究了整个非洲北部气候、湖泊和植被之间的动态相互作用。此外,我们还研究了湖泊深度变化对全新世中期降水量的影响,这是以往模拟研究中被忽视的一个方面。工业化前的对照模拟显示,DEL 模型真实地模拟了整个非洲北部的湖泊范围。只有在 Ahnet 和 Chotts 盆地,湖泊面积被略微高估,这可能与模拟的分辨率较低有关。全新世中期的模拟结果表明,湖泊扩张和植被扩张都导致了非洲北部降水量的增加。然而,这些因素对降水量的单独贡献之和要大于湖泊和植被动态相互作用产生的综合效应。因此,湖泊与植被的相互作用导致整个萨赫勒地区相对干燥。造成这种干燥响应的主要原因是,模拟植被扩张对陆地表面的冷却作用比湖泊扩张更强,而湖泊扩张主要是由乍得湖的扩张造成的。因此,乍得湖地区的地表温度升高,导致局部经向地表温度梯度发生变化。经向地表-温度梯度的这些变化与从热带大西洋进入萨赫勒地区的内陆水汽输送减少有关,从而导致萨赫勒地区的干燥反应。一个理想化的全新世中期实验表明,在不改变水平湖泊面积的情况下,乍得湖水深减少约 1-5 米,也会引起类似的干燥反应。通过降低乍得湖的深度,湖泊的蓄热能力下降,夏季湖泊升温更快。因此,在 ICON-JSBACH4 模型中,湖泊深度极大地影响了模拟地表温度以及模拟湖泊与植被之间的经向地表温度梯度,从而影响了全新世中期非洲北部的降水量。
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来源期刊
Climate of The Past
Climate of The Past 地学-气象与大气科学
CiteScore
7.40
自引率
14.00%
发文量
120
审稿时长
4-8 weeks
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.
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