为马里兰州和宾夕法尼亚州的气候智能型森林管理和木材利用模拟气候缓解潜力

IF 2.7 3区 农林科学 Q2 ECOLOGY Frontiers in Forests and Global Change Pub Date : 2023-11-07 DOI:10.3389/ffgc.2023.1259010
Chad C. Papa, Kendall DeLyser, Kylie Clay, Daphna Gadoth-Goodman, Lauren Cooper, Werner A. Kurz, Michael Magnan, Todd Ontl
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引用次数: 0

摘要

州和地方政府越来越有兴趣了解森林和采伐木材产品在区域碳汇和储存中的作用,它们对州一级温室气体(GHG)减排的潜在贡献,以及温室气体减排目标与潜在经济机会之间的相互作用。本文采用基于系统的方法,采用基于经验驱动过程的森林碳动态和采伐木材产品模型,对2007年至2100年马里兰州和宾夕法尼亚州各种森林管理和木材利用活动的碳影响进行了预测。为了量化全州森林碳动态,我们将森林清查数据、采伐和管理活动数据以及土地利用变化和天然林干扰的遥感指标整合到参与式建模方法中。我们考虑了以下方面的温室气体净排放:(1)森林生态系统;(2)采伐的木材产品;(3)木材产品利用带来的替代效益;(4)与州内采伐活动减少相关的泄漏。根据州机构合作伙伴的输入,马里兰州和宾夕法尼亚州分别模拟了15个和13个管理情景,每个州分别模拟了两个气候变化影响情景和两个生物能源情景。我们的研究结果表明,相对于一切照旧的做法,战略性森林管理和木材利用都可以提供巨大的减缓气候变化的潜力,到2030年,在不中断木材供应的情况下,马里兰州和宾夕法尼亚州的森林碳汇分别增加29%和38%。关键的气候智慧型森林管理活动包括维持和扩大森林面积,培养森林恢复力和自然再生能力,鼓励可持续采伐做法,平衡木材供应和木材利用与树木生长之间的关系,以及为未来的气候影响做好准备。本研究为量化森林生长、森林干扰和采伐木材产品利用之间的关系以及它们对碳储量和通量的集体影响的大量工作提供了补充,以确定增强森林碳汇的途径,以支持国家级净零排放目标。
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Modeling climate-smart forest management and wood use for climate mitigation potential in Maryland and Pennsylvania
State and local governments are increasingly interested in understanding the role forests and harvested wood products play in regional carbon sinks and storage, their potential contributions to state-level greenhouse gas (GHG) reductions, and the interactions between GHG reduction goals and potential economic opportunities. We used empirically driven process-based forest carbon dynamics and harvested wood product models in a systems-based approach to project the carbon impacts of various forest management and wood utilization activities in Maryland and Pennsylvania from 2007 to 2100. To quantify state-wide forest carbon dynamics, we integrated forest inventory data, harvest and management activity data, and remotely-sensed metrics of land-use change and natural forest disturbances within a participatory modeling approach. We accounted for net GHG emissions across (1) forest ecosystems (2) harvested wood products, (3) substitution benefits from wood product utilization, and (4) leakage associated with reduced in-state harvesting activities. Based on state agency partner input, a total of 15 management scenarios were modeled for Maryland and 13 for Pennsylvania, along with two climate change impact scenarios and two bioenergy scenarios for each state. Our findings show that both strategic forest management and wood utilization can provide substantial climate change mitigation potential relative to business-as-usual practices, increasing the forest C sink by 29% in Maryland and 38% in Pennsylvania by 2030 without disrupting timber supplies. Key climate-smart forest management activities include maintaining and increasing forest extent, fostering forest resiliency and natural regeneration, encouraging sustainable harvest practices, balancing timber supply and wood utilization with tree growth, and preparing for future climate impacts. This study adds to a growing body of work that quantifies the relationships between forest growth, forest disturbance, and harvested wood product utilization, along with their collective influence on carbon stocks and fluxes, to identify pathways to enhance forest carbon sinks in support of state-level net-zero emission targets.
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CiteScore
4.50
自引率
6.20%
发文量
256
审稿时长
12 weeks
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