索洛山毛林24年净碳生态系统交换——与物候和气候的关系

K. Pilegaard, A. Ibrom
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引用次数: 9

摘要

植物通过光合作用进行的碳固存负责清除大量人为排放到大气中的二氧化碳。近年来,这个所谓的陆地碳汇已经消除了大约30%的人为排放到大气中,其中森林是最重要的碳汇。然而,陆地汇很容易受到环境变化的影响,比如大气成分、气候变化以及风暴和干旱等极端事件。因此,重要的是研究这种变化对陆地生态系统的影响,为预测碳汇的未来提供依据。我们在这里报告了1996年至2019年期间丹麦山毛榉森林连续二氧化碳通量测量的结果。多年来,森林扮演着二氧化碳汇的角色,其净碳固存量约为0至400克/立方米/年。我们发现,净生态系统交换(NEE)(以15 g C m-2年的绝对值增加)、总生态系统交换(GEE)(以25 g C m-2年的绝对值增加)和生态系统呼吸(RE)(以10 g C m-2年的绝对值增加)呈显著趋势。生长季节延长解释了NEE增长的73%。大气中二氧化碳浓度的增加和随后光合作用能力的增加,再加上气候变暖,最有可能是碳吸收增加的主要原因。2018年夏季的严重干旱导致年度新能源效益减少了25%。
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Net carbon ecosystem exchange during 24 years in the Sorø Beech Forest – relations to phenology and climate
Abstract The carbon sequestration of plants through photosynthesis is responsible for removal of a substantial amount of the man-made CO2 emissions to the atmosphere. In recent years this so-called land-sink has removed about 30% of the man-made emissions to the atmosphere, with forests being the most important sinks. The land-sink is, however, vulnerable to changes in the environment, such as the atmospheric composition, climate change, and extreme events like storms and droughts. It is therefore important to study the effects of such change on terrestrial ecosystems to provide the basis for predicting the future of the sink. We here report the results of continuous CO2 flux measurements over a Danish beech forest during the years 1996–2019. Over the years the forest acted as a sink of CO2 with a net carbon sequestration ranging from about zero to 400 g C m–2 yr−1. We found significant trends in net ecosystem exchange (NEE) (increasing in absolute terms with 15 g C m–2 yr2), gross ecosystem exchange (GEE) (increasing with 25 g C m–2 yr–2), and ecosystem respiration (RE) (increasing with 10 g C m–2 yr–2). A prolonged growing season explained 73% of the increase in NEE. The increasing CO2 concentration in the atmosphere and a subsequent increase in photosynthetic capacity together with warming are the most likely main causes of the increased carbon uptake. The severe drought in the summer of 2018 resulted in a reduction of the annual NEE of 25%.
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