Forest Carbon Storage in the Western United States: Distribution, Drivers, and Trends

IF 7.3 1区 地球科学 Q1 ENVIRONMENTAL SCIENCES Earths Future Pub Date : 2024-07-11 DOI:10.1029/2023EF004399
Jazlynn Hall, Manette E. Sandor, Brian J. Harvey, Sean A. Parks, Anna T. Trugman, A. Park Williams, Winslow D. Hansen
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Abstract

Forests are a large carbon sink and could serve as natural climate solutions that help moderate future warming. Thus, establishing forest carbon baselines is essential for tracking climate-mitigation targets. Western US forests are natural climate solution hotspots but are profoundly threatened by drought and altered disturbance regimes. How these factors shape spatial patterns of carbon storage and carbon change over time is poorly resolved. Here, we estimate live and dead forest carbon density in 19 forested western US ecoregions with national inventory data (2005–2019) to determine: (a) current carbon distributions, (b) underpinning drivers, and (c) recent trends. Potential drivers of current carbon included harvest, wildfire, insect and disease, topography, and climate. Using random forests, we evaluated driver importance and relationships with current live and dead carbon within ecoregions. We assessed trends using linear models. Pacific Northwest (PNW) and Southwest (SW) ecoregions were most and least carbon dense, respectively. Climate was an important carbon driver in the SW and Lower Rockies. Fire reduced live and increased dead carbon, and was most important in the Upper Rockies and California. No ecoregion was unaffected by fire. Harvest and private ownership reduced carbon, particularly in the PNW. Since 2005, live carbon declined across much of the western US, likely from drought and fire. Carbon has increased in PNW ecoregions, likely recovering from past harvest, but recent record fire years may alter trajectories. Our results provide insight into western US forest carbon function and future vulnerabilities, which is vital for effective climate change mitigation strategies.

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美国西部的森林碳储存:分布、驱动因素和趋势
森林是一个巨大的碳汇,可以作为自然气候解决方案,帮助减缓未来的气候变暖。因此,建立森林碳基线对于跟踪气候减缓目标至关重要。美国西部的森林是自然气候解决方案的热点地区,但却深受干旱和扰动机制改变的威胁。这些因素如何形成碳储存的空间模式和碳随时间的变化,目前还没有得到很好的解决。在此,我们利用国家清查数据(2005-2019 年)估算了美国西部 19 个森林生态区的活林和死林碳密度,以确定:(a)当前的碳分布;(b)基本驱动因素;以及(c)近期趋势。当前碳的潜在驱动因素包括采伐、野火、昆虫和疾病、地形和气候。利用随机森林,我们评估了生态区内驱动因素的重要性以及与当前活碳和死碳的关系。我们使用线性模型评估了趋势。西北太平洋生态区(PNW)和西南生态区(SW)的碳密度分别最高和最低。气候是西南部和下落基山脉的重要碳驱动因素。火灾减少了活碳,增加了死碳,在上落基山脉和加利福尼亚最为重要。没有一个生态区不受火灾影响。采伐和私有制减少了碳,尤其是在西北太平洋地区。自 2005 年以来,美国西部大部分地区的活碳减少,这可能是干旱和火灾造成的。西北太平洋生态区域的碳有所增加,可能是从过去的采伐中恢复过来的,但最近创纪录的火灾年份可能会改变这一轨迹。我们的研究结果让人们深入了解了美国西部森林碳功能和未来的脆弱性,这对有效的气候变化减缓战略至关重要。
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来源期刊
Earths Future
Earths Future ENVIRONMENTAL SCIENCESGEOSCIENCES, MULTIDI-GEOSCIENCES, MULTIDISCIPLINARY
CiteScore
11.00
自引率
7.30%
发文量
260
审稿时长
16 weeks
期刊介绍: Earth’s Future: A transdisciplinary open access journal, Earth’s Future focuses on the state of the Earth and the prediction of the planet’s future. By publishing peer-reviewed articles as well as editorials, essays, reviews, and commentaries, this journal will be the preeminent scholarly resource on the Anthropocene. It will also help assess the risks and opportunities associated with environmental changes and challenges.
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