Regional water cycle sensitivity to afforestation: synthetic numerical experiments for tropical Africa

IF 3.3 Q2 ENVIRONMENTAL SCIENCES
Joël Arnault, Anthony Musili Mwanthi, Tanja Portele, Lu Li, Thomas Rummler, Benjamin Fersch, Mohammed Abdullahi Hassan, Titike Kassa Bahaga, Zhenyu Zhang, Eric Mensah Mortey, Ifeany Chukwudi Achugbu, Hassane Moutahir, Souleymane Sy, Jianhui Wei, Patrick Laux, Stefan Sobolowski, Harald Kunstmann
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Abstract

Afforestation as a climate change mitigation option has been the subject of intense debate and study over the last few decades, particularly in the tropics where agricultural activity is expanding. However, the impact of such landcover changes on the surface energy budget, temperature, and precipitation remains unclear as feedbacks between various components are difficult to resolve and interpret. Contributing to this scientific debate, regional climate models of varying complexity can be used to test how regional climate reacts to afforestation. In this study, the focus is on the gauged Nzoia basin (12,700 km 2 ) located in a heavily farmed region of tropical Africa. A reanalysis product is dynamically downscaled with a coupled atmospheric-hydrological model (WRF-Hydro) to finely resolve the land-atmosphere system in the Nzoia region. To overcome the problem of Nzoia river flooding over its banks we enhance WRF-Hydro with an overbank flow routing option, which improves the representation of daily discharge based on the Nash-Sutcliffe efficiency and Kling-Gupta efficiency (from −2.69 to 0.30, and −0.36 to 0.63, respectively). Changing grassland and cropland areas to savannas, woody savannas, and evergreen broadleaf forest in three synthetic numerical experiments allows the assessment of potential regional climate impacts of three afforestation strategies. In all three cases, the afforestation-induced decrease in soil evaporation is larger than the afforestation-induced increase in plant transpiration, thus increasing sensible heat flux and triggering a localized negative feedback process leading to more precipitation and more runoff. This effect is more pronounced with the woody savannas experiment, with 7% less evapotranspiration, but 13% more precipitation, 8% more surface runoff, and 12% more underground runoff predicted in the Nzoia basin. This study demonstrates a potentially large impact of afforestation on regional water resources, which should be investigated in more detail for policy making purposes.
区域水循环对造林的敏感性:热带非洲的综合数值试验
造林作为减缓气候变化的一种选择,在过去几十年中一直是激烈辩论和研究的主题,特别是在农业活动不断扩大的热带地区。然而,由于各组分之间的反馈难以解析和解释,这种地表覆盖变化对地表能量收支、温度和降水的影响尚不清楚。不同复杂程度的区域气候模型可以用来测试区域气候对植树造林的反应,这有助于这场科学辩论。在这项研究中,重点是位于热带非洲重度农业地区的Nzoia盆地(12,700平方公里)。利用大气-水文耦合模式(WRF-Hydro)对再分析结果进行了动态缩比,以精细解析Nzoia地区的陆地-大气系统。为了克服Nzoia河两岸洪水泛滥的问题,我们通过河岸上的水流路径选项增强了WRF-Hydro,这提高了基于Nash-Sutcliffe效率和Kling-Gupta效率(分别从- 2.69到0.30和- 0.36到0.63)的日流量表示。在三个综合数值实验中,将草地和耕地面积转变为稀树草原、木本稀树草原和常绿阔叶林,可以评估三种造林策略对区域气候的潜在影响。在这三种情况下,造林引起的土壤蒸发量减少大于植物蒸腾的增加,从而增加了感热通量,引发了局部负反馈过程,导致降水和径流增加。这种影响在木本稀树草原实验中更为明显,在Nzoia盆地,预计蒸发蒸腾减少7%,但降水增加13%,地表径流增加8%,地下径流增加12%。这项研究表明造林对区域水资源的潜在巨大影响,应对此进行更详细的调查,以便制定政策。
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
Frontiers in Climate
Frontiers in Climate Environmental Science-Environmental Science (miscellaneous)
CiteScore
4.50
自引率
0.00%
发文量
233
审稿时长
15 weeks
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