Modelling branch surface area of Picea abies [L.] Karst

IF 1.8 3区 农林科学 Q2 FORESTRY
Mathias Neumann, Thomas Ledermann
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Abstract

ABSTRACTAllometric models based on limited sub-samples are widely used for predicting forest-scale information. Here, we develop allometric models for the branch surface area of the widespread conifer species Picea abies [L.] Karst. Branch surface area is a proxy for the capacity of tree branches to intercept and store water and air pollutants. Based on “probability proportional to size” sampling, we measured the surface area for 285 branches and then calculated the branch surface area of 30 trees (and their 3298 branches). We developed allometric models to estimate the total surface area of branches, as well as their number and diameters, for trees across a range of diameters (DBH), heights, and crown ratios (CR). We show that DBH and CR play significant roles in branch characteristics. The branch surface area was linearly related to the stand basal area. Reducing stand density will proportionally reduce interception capacity. The approach outlined here may help stimulate further studies (more species, regions, and management practices) required to optimize stand density for ecosystem services related to crown characteristics, such as hydrology, forage quality, and quantity or capacity for air pollutants.KEYWORDS: Precipitation interceptionwater capacitybarkNorway sprucehydrology-oriented silviculturePPS sampling AcknowledgementsBranch and tree data were sampled on long-term research plots (LTRP) of the Department of Forest Growth, Silviculture and Genetics of the Austrian Research Centre for Forests (BFW). The maintenance of such LTRP is one of the core tasks of BFW and is financed through the base funding of BFW provided by the Austrian Federal Ministry of Agriculture, Forestry, Regions, and Water Management. The authors are grateful for this support. Moreover, the authors want to thank Gerald Schnabel for the preparation of Figure 2. The analysis was partly funded by the European Union Horizon Europe programme as part of the project ‘OPTimising FORest management decisions for a low-carbon, climate resilient future in Europe’ (OptFor-EU), under Grant agreement n°101060554. Views and opinions expressed are however those of the authors only and do not necessarily reflect those of the European Union or REA. Neither the European Union nor the granting authority can be held responsible for them.Disclosure statementNo potential conflict of interest was reported by the authors.Data availability statementThe data used in this study will be made available upon request.
云杉树枝表面积建模[j]。)岩溶
摘要基于有限子样本的异速生长模型被广泛用于森林尺度信息的预测。在此,我们建立了广泛分布的针叶树种云杉(Picea abies)树枝表面积的异速生长模型[L]。岩溶。树枝表面积是树枝拦截和储存水和空气污染物的能力的代表。基于“概率与大小成正比”抽样,我们测量了285个树枝的表面积,然后计算了30棵树(及其3298个树枝)的树枝表面积。我们开发了异速生长模型来估算不同直径(DBH)、高度和冠度比(CR)范围内树木的树枝总表面积、数量和直径。研究表明,胸径和胸径对树枝特征有重要影响。枝条表面积与林分基面积呈线性相关。减少林分密度将成比例地降低拦截能力。本文概述的方法可能有助于促进进一步的研究(更多的物种、区域和管理实践),以优化林分密度,以实现与林冠特征(如水文、饲料质量和空气污染物的数量或容量)相关的生态系统服务。关键词:降水截留,水容量,森林,挪威云杉,水文导向的林业,pps采样确认,在奥地利森林研究中心(BFW)森林生长,林业和遗传部的长期研究地块(LTRP)上采样了树枝和树木数据。维持这样的ltp是奥地利联邦农业、林业、地区和水管理部的核心任务之一,由奥地利联邦农业、林业、地区和水管理部提供的基础资金资助。作者非常感谢这种支持。此外,作者要感谢Gerald Schnabel为图2所做的准备。该分析部分由欧盟地平线欧洲计划资助,作为“优化森林管理决策,实现欧洲低碳、气候适应型未来”(opt - for - eu)项目的一部分,根据第101060554号赠款协议。然而,所表达的观点和意见仅代表作者的观点和意见,并不一定反映欧盟或REA的观点和意见。欧盟和授权机构都不能对此负责。披露声明作者未报告潜在的利益冲突。数据可用性声明本研究中使用的数据将根据要求提供。
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来源期刊
CiteScore
3.00
自引率
5.60%
发文量
26
审稿时长
3.3 months
期刊介绍: The Scandinavian Journal of Forest Research is a leading international research journal with a focus on forests and forestry in boreal and temperate regions worldwide.
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