利用地面激光扫描评估北加州不同森林的非破坏性地上生物量异速生长

P. Krause, Brieanne Forbes, Alexander Barajas-Ritchie, M. Clark, M. Disney, P. Wilkes, L. Bentley
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引用次数: 2

摘要

碳核算的一个关键部分是使用异速生长方程来量化树木的地上生物量(AGB),但是特定物种的方程是有限的,因为这些方程的数据需要对许多树木进行破坏性的采伐,这既困难又耗时。本文采用陆地激光扫描(TLS)技术,利用定量结构模型(QSMs)估算的树干和树枝体积以及文献中的木材密度,对北加州3个地点5种282棵树木的AGB进行了无损估算。然后,我们将TLS QSM估计的AGB与已发表的异速生长方程进行比较,并使用基于TLS的AGB、胸径(DBH)和高度推导出新的物种特异性异速生长AGB方程。为了验证TLS的使用,我们使用传统的林业方法收集了单株树木的胸径(n = 550)和高度(n = 291)数据。基于tls的胸径和高度与实地调查数据差异不显著(胸径r2 = 0.98,高度r2 = 0.95)。在所有物种中,根据TLS QSM计算的AGB比使用已公布的林业局森林清盘和分析程序方程计算的AGB高约30%,TLS QSM估计的AGB比使用现有方程计算的AGB高10%,尽管这种差异与物种有关。特别是,栎和红杉的TLS AGB估计值与使用已发表的方程计算的AGB估计值差异最大。使用包含胸径和高度的TLS数据创建的新异速生长方程比仅包含胸径的方程表现更好,并且与QSMs生成的AGB估计值最匹配。我们的研究结果支持将TLS作为一种方法,在确定树种和木材密度的情况下,在样地水平上快速估计多棵树木的高度、胸径和AGB。此外,为我们的5个研究物种建立新的基于tls的非破坏性异速生长方程可能对更大空间尺度上的碳定量具有重要的应用和意义,特别是因为我们的方程比以前的方法估计了更大的AGB。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Using terrestrial laser scanning to evaluate non-destructive aboveground biomass allometries in diverse Northern California forests
A crucial part of carbon accounting is quantifying a tree’s aboveground biomass (AGB) using allometric equations, but species-specific equations are limited because data to inform these equations requires destructive harvesting of many trees which is difficult and time-consuming. Here, we used terrestrial laser scanning (TLS) to non-destructively estimate AGB for 282 trees from 5 species at 3 locations in Northern California using stem and branch volume estimates from quantitative structure models (QSMs) and wood density from the literature. We then compared TLS QSM estimates of AGB with published allometric equations and used TLS-based AGB, diameter at breast height (DBH), and height to derive new species-specific allometric AGB equations for our study species. To validate the use of TLS, we used traditional forestry approaches to collect DBH (n = 550) and height (n = 291) data on individual trees. TLS-based DBH and height were not significantly different from field inventory data (R 2 = 0.98 for DBH, R 2 = 0.95 for height). Across all species, AGB calculated from TLS QSM volumes were approximately 30% greater than AGB estimates using published Forest Service’s Forest Inventory and Analysis Program equations, and TLS QSM AGB estimates were 10% greater than AGB calculated with existing equations, although this variation was species-dependent. In particular, TLS AGB estimates for Quercus agrifolia and Sequoia sempervirens differed the most from AGB estimates calculated using published equations. New allometric equations created using TLS data with DBH and height performed better than equations that only included DBH and matched most closely with AGB estimates generated from QSMs. Our results support the use of TLS as a method to rapidly estimate height, DBH, and AGB of multiple trees at a plot-level when species are identified and wood density is known. In addition, the creation of new TLS-based non-destructive allometric equations for our 5 study species may have important applications and implications for carbon quantification over larger spatial scales, especially since our equations estimated greater AGB than previous approaches.
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