量化关键因素对受管理温带森林碳减排潜力的影响。

IF 3.9 3区 环境科学与生态学 Q2 ENVIRONMENTAL SCIENCES
Konstantin Gregor, Andreas Krause, Christopher P. O. Reyer, Thomas Knoke, Benjamin F. Meyer, Susanne Suvanto, Anja Rammig
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引用次数: 0

摘要

背景:森林通过森林和木制品中的碳汇以及木制品替代碳密集型材料和燃料时产生的替代效应,降低大气中的二氧化碳浓度,从而减缓气候变化。由于受到多种重要因素的影响,如森林年龄和类型、气候变化和相关自然干扰、采伐强度、木材使用模式、抢救性采伐实践以及替代产品的碳强度等,量化森林的碳减排潜力极具挑战性。在此,我们以中欧(巴伐利亚)森林为例,通过生态系统模型的因子模拟实验,建立了一个量化这些因素影响的框架:我们的模拟结果表明,幼林的减排潜力高于成熟林,阔叶林和针叶林的减排潜力相似。长寿命木材产品对减缓气候变化有很大的贡献,尤其是针叶林,因为它们有木材产品组合,而且增加木材的材料使用量对气候也有相当大的好处。因此,在针叶林不断向阔叶林转化的同时,应推广阔叶树种的长寿命产品,以保持产品汇。气候变化(尤其是日益加剧的干扰)和去碳化是影响减缓潜力的最关键因素之一,并带来了很大的不确定性。不过,在 2050 年之前,这种不确定性很小,足以得出可靠的结论。例如,在我们的模拟中,降低收获强度增强了碳汇,但削弱了替代效应,从而导致 2050 年前的总减排潜力下降。然而,当考虑到更长的时间跨度(即直到 2100 年)时,由于预期的去碳化,替代效应在我们的模拟中变得足够低,因此减少收获量往往似乎是更有利的解决方案:我们的研究结果表明,有必要根据不同森林地点的具体情况制定相应的减缓战略。此外,考虑替代效应和全面评估使用木制品所避免的排放量对于确定减排潜力至关重要。虽然短期建议是可行的,但我们建议采用风险分散和稳健优化等方法来应对气候变化和 2050 年后去碳化步伐带来的越来越多的不确定性。最后,遏制排放可减少气候变化对森林的威胁,保护森林的碳汇和生态系统服务。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Quantifying the impact of key factors on the carbon mitigation potential of managed temperate forests

Background

Forests mitigate climate change by reducing atmospheric \(\mathrm {CO_2}\)-concentrations through the carbon sink in the forest and in wood products, and substitution effects when wood products replace carbon-intensive materials and fuels. Quantifying the carbon mitigation potential of forests is highly challenging due to the influence of multiple important factors such as forest age and type, climate change and associated natural disturbances, harvest intensities, wood usage patterns, salvage logging practices, and the carbon-intensity of substituted products. Here, we developed a framework to quantify the impact of these factors through factorial simulation experiments with an ecosystem model at the example of central European (Bavarian) forests.

Results

Our simulations showed higher mitigation potentials of young forests compared to mature forests, and similar ones in broad-leaved and needle-leaved forests. Long-lived wood products significantly contributed to mitigation, particularly in needle-leaved forests due to their wood product portfolio, and increased material usage of wood showed considerable climate benefits. Consequently, the ongoing conversion of needle-leaved to more broad-leaved forests should be accompanied by the promotion of long-lived products from broad-leaved species to maintain the product sink. Climate change (especially increasing disturbances) and decarbonization were among the most critical factors influencing mitigation potentials and introduced substantial uncertainty. Nevertheless, until 2050 this uncertainty was narrow enough to derive robust findings. For instance, reducing harvest intensities enhanced the carbon sink in our simulations, but diminished substitution effects, leading to a decreased total mitigation potential until 2050. However, when considering longer time horizons (i.e. until 2100), substitution effects became low enough in our simulations due to expected decarbonization such that decreasing harvests often seemed the more favorable solution.

Conclusion

Our results underscore the need to tailor mitigation strategies to the specific conditions of different forest sites. Furthermore, considering substitution effects, and thoroughly assessing the amount of avoided emissions by using wood products, is critical to determine mitigation potentials. While short-term recommendations are possible, we suggest risk diversification and methodologies like robust optimization to address increasing uncertainties from climate change and decarbonization paces past 2050. Finally, curbing emissions reduces the threat of climate change on forests, safeguarding their carbon sink and ecosystem services.

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来源期刊
Carbon Balance and Management
Carbon Balance and Management Environmental Science-Management, Monitoring, Policy and Law
CiteScore
7.60
自引率
0.00%
发文量
17
审稿时长
14 weeks
期刊介绍: Carbon Balance and Management is an open access, peer-reviewed online journal that encompasses all aspects of research aimed at developing a comprehensive policy relevant to the understanding of the global carbon cycle. The global carbon cycle involves important couplings between climate, atmospheric CO2 and the terrestrial and oceanic biospheres. The current transformation of the carbon cycle due to changes in climate and atmospheric composition is widely recognized as potentially dangerous for the biosphere and for the well-being of humankind, and therefore monitoring, understanding and predicting the evolution of the carbon cycle in the context of the whole biosphere (both terrestrial and marine) is a challenge to the scientific community. This demands interdisciplinary research and new approaches for studying geographical and temporal distributions of carbon pools and fluxes, control and feedback mechanisms of the carbon-climate system, points of intervention and windows of opportunity for managing the carbon-climate-human system. Carbon Balance and Management is a medium for researchers in the field to convey the results of their research across disciplinary boundaries. Through this dissemination of research, the journal aims to support the work of the Intergovernmental Panel for Climate Change (IPCC) and to provide governmental and non-governmental organizations with instantaneous access to continually emerging knowledge, including paradigm shifts and consensual views.
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