Disentangling the contributions of ecological conditions to biomass in longleaf pine forests

IF 3.7 2区 农林科学 Q1 FORESTRY
Olufemi E. Fatunsin , Christina Staudhammer , Justin Hart , Paige Ferguson
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Abstract

Theoretical and empirical studies have suggested that climate, soils, and topography are the primary drivers of aboveground biomass in forests. Yet, the direct effects of these drivers may be mediated by indirect effects, such as species diversity and structural diversity. This study investigates the relationships between climate, topography, soil fertility, species diversity, structural diversity, and aboveground biomass (AGB) using Structural Equation Modeling (SEM) to distinguish indirect and direct causal relationships. We conducted this study in longleaf pine (Pinus palustris)-dominated forests in the southeastern United States (SEUS), using United States Department of Agriculture Forest Service inventory data from 2015 to 2019. The longleaf pine ecosystems of the SEUS are of great importance due to their rich biodiversity and unique ecological functions, but they also provide an opportunity for scientific studies across a large ecological gradient because they exist across a wide range of edaphic conditions. However, studies in longleaf pine have primarily focused on stand structure, regeneration processes, prescribed fire practices, and groundcover restoration, leaving a knowledge gap regarding AGB in this ecosystem. We hypothesized that (1) climate, topography, and soil fertility would influence AGB through positive indirect effects; (2) structural diversity rather than species diversity would strongly mediate the response of AGB to climate, topography, and soil fertility; and (3) species diversity and structural diversity would be positively correlated, with structural diversity positively impacting AGB across coarse scale ecological gradients. Structural diversity could be important in predicting AGB because it reflects the horizontal complexity of the forest stand. Our results show that mean annual temperature and slope had considerable direct negative and positive impacts on AGB, respectively. Additionally, soil fertility, elevation, and precipitation indirectly impacted AGB by affecting species diversity. Specifically, AGB decreased in highly fertile soils, whereas elevation and precipitation led to an increase in tree species diversity. Structural diversity had a direct positive influence on AGB, while species diversity played an indirect role by promoting structural diversity. While there are diverse objectives for managing longleaf pine, management that promotes high levels of stand structural diversity may strengthen the stock of longleaf pine forest AGB, which could be especially important in the face of changing climatic conditions. Our findings emphasize the importance of integrating climate resilience and carbon storage goals into forest management practices.

厘清生态条件对长叶松林生物量的影响
理论和实证研究表明,气候、土壤和地形是森林地上生物量的主要驱动因素。然而,这些驱动因素的直接影响可能会受到物种多样性和结构多样性等间接影响的介导。本研究使用结构方程模型(SEM)来区分间接和直接因果关系,从而研究气候、地形、土壤肥力、物种多样性、结构多样性和地上生物量(AGB)之间的关系。我们在美国东南部(SEUS)以长叶松(Pinus palustris)为主的森林中开展了这项研究,使用的是美国农业部林业局 2015 年至 2019 年的清查数据。美国东南部的长叶松生态系统因其丰富的生物多样性和独特的生态功能而具有重要意义,同时也因其存在于各种不同的气候条件下,为跨越巨大的生态梯度进行科学研究提供了机会。然而,对长叶松的研究主要集中在林分结构、再生过程、规定火力实践和地被植物恢复等方面,因此对该生态系统中的 AGB 一无所知。我们假设:(1) 气候、地形和土壤肥力将通过正向间接效应影响 AGB;(2) 结构多样性(而非物种多样性)将在很大程度上介导 AGB 对气候、地形和土壤肥力的响应;(3) 物种多样性和结构多样性呈正相关,结构多样性对粗尺度生态梯度的 AGB 有正向影响。结构多样性反映了林分的水平复杂性,因此对预测AGB很重要。我们的研究结果表明,年平均温度和坡度分别对AGB有相当大的直接负面和正面影响。此外,土壤肥力、海拔高度和降水量也会影响物种多样性,从而间接影响AGB。具体地说,高肥力土壤的 AGB 会降低,而海拔和降水则会导致树种多样性增加。结构多样性对AGB有直接的积极影响,而物种多样性则通过促进结构多样性发挥间接作用。虽然长叶松的管理目标多种多样,但促进高水平林分结构多样性的管理可能会加强长叶松林AGB的存量,这在面对不断变化的气候条件时尤为重要。我们的发现强调了将气候适应能力和碳储存目标纳入森林管理实践的重要性。
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来源期刊
Forest Ecology and Management
Forest Ecology and Management 农林科学-林学
CiteScore
7.50
自引率
10.80%
发文量
665
审稿时长
39 days
期刊介绍: Forest Ecology and Management publishes scientific articles linking forest ecology with forest management, focusing on the application of biological, ecological and social knowledge to the management and conservation of plantations and natural forests. The scope of the journal includes all forest ecosystems of the world. A peer-review process ensures the quality and international interest of the manuscripts accepted for publication. The journal encourages communication between scientists in disparate fields who share a common interest in ecology and forest management, bridging the gap between research workers and forest managers. We encourage submission of papers that will have the strongest interest and value to the Journal''s international readership. Some key features of papers with strong interest include: 1. Clear connections between the ecology and management of forests; 2. Novel ideas or approaches to important challenges in forest ecology and management; 3. Studies that address a population of interest beyond the scale of single research sites, Three key points in the design of forest experiments, Forest Ecology and Management 255 (2008) 2022-2023); 4. Review Articles on timely, important topics. Authors are welcome to contact one of the editors to discuss the suitability of a potential review manuscript. The Journal encourages proposals for special issues examining important areas of forest ecology and management. Potential guest editors should contact any of the Editors to begin discussions about topics, potential papers, and other details.
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