The impacts of elevated CO2 on forest growth, mortality, and recovery in the Amazon rainforest

Yitong Yao, P. Ciais, E. Joetzjer, Wei Li, Lei Zhu, Yujie Wang, Christian Frankenberg, N. Viovy
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Abstract

Abstract. The Amazon rainforest plays a crucial role in global carbon storage, but a minor destabilization of these forests could result in considerable carbon loss. Among the external factors affecting vegetation, elevated CO2 (eCO2) levels have long been anticipated to have positive impacts on vegetation, including the direct enhancement of both photosynthesis and productivity and increasing water use efficiency. However, the overall impact of eCO2 on the net carbon balance, especially concerning tree-mortality-induced carbon loss and recovery following extreme drought events, has remained elusive. Here, we use a process-based model that couples physiological CO2 effects with demography and both drought mortality and resistance processes. The model was previously calibrated to reproduce observed drought responses of Amazon forest sites. The model results, based on factorial simulations with and without eCO2, reveal that eCO2 enhances forest growth and promotes competition between trees, leading to more natural self-thinning of forest stands. This occurs following a growth–mortality trade-off response, although the growth outweighs the tree loss. Additionally, eCO2 provides water-saving benefits, reducing the risk of tree mortality during drought episodes. However, extra carbon losses could still occur due to an eCO2-induced increase in background biomass density, leading to “more carbon available to lose” when severe droughts happen. Furthermore, we found that eCO2 accelerates drought recovery and enhances drought resistance and resilience. By delving into the less-explored aspect of tree mortality response to eCO2, the model improvements advance our understanding of how carbon balance responds to eCO2, particularly regarding mechanisms of continuous competition-induced carbon loss vs. pulses of drought-induced carbon loss. These findings provide valuable insights into the intricate ways in which rising CO2 influences forest carbon dynamics and vulnerability, offering a critical understanding of the Amazon rainforest's evolution amidst more frequent and intense extreme climate events.
高浓度二氧化碳对亚马逊雨林森林生长、死亡和恢复的影响
摘要亚马逊雨林在全球碳储存中发挥着至关重要的作用,但这些森林的轻微不稳定就会导致大量的碳损失。在影响植被的外部因素中,二氧化碳(eCO2)水平的升高一直被认为会对植被产生积极影响,包括直接提高光合作用和生产力,以及提高水分利用效率。然而,二氧化碳升高对净碳平衡的总体影响,尤其是对树木枯死引起的碳损失和极端干旱事件后的碳恢复的影响,仍然难以捉摸。在这里,我们使用了一个基于过程的模型,该模型将二氧化碳的生理效应与人口统计以及干旱死亡和抵抗过程结合起来。该模型之前经过校准,再现了亚马逊森林地区观测到的干旱反应。模型结果基于有无二氧化碳的因子模拟,揭示了二氧化碳会促进森林生长并促进树木之间的竞争,从而导致林分更自然的自我疏伐。尽管树木的生长超过了树木的损失,但这是在生长-死亡权衡反应之后发生的。此外,eCO2 还能带来节水效益,降低干旱期间树木死亡的风险。然而,由于 eCO2 引起的背景生物量密度增加,当发生严重干旱时,仍可能出现额外的碳损失,导致 "更多的碳损失"。此外,我们还发现,eCO2 能加速干旱恢复,增强抗旱性和恢复力。通过深入研究树木死亡对 eCO2 的响应这一较少被探索的方面,模型的改进推进了我们对碳平衡如何响应 eCO2 的理解,特别是对持续竞争引起的碳损失与干旱引起的碳损失脉冲机制的理解。这些发现为我们深入了解二氧化碳上升影响森林碳动态和脆弱性的复杂方式提供了宝贵的视角,为我们理解亚马逊雨林在更频繁、更剧烈的极端气候事件中的演变提供了重要依据。
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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