Grupo de Ecología y Restauración Forestal, Departamento de Ciencias de la Vida, Universidad de Alcalá, ctra. Madrid-Barcelona, km 33.4, 28805, Alcalá de Henares, Spain; Climate Change Impacts and Risks in the Anthropocene (C-CIA), Institute for Environmental Sciences (IES), University of Geneva, 66 Boulevard Carl-Vogt, CH-1205, Switzerland.
Grupo de Ecología y Restauración Forestal, Departamento de Ciencias de la Vida, Universidad de Alcalá, ctra. Madrid-Barcelona, km 33.4, 28805, Alcalá de Henares, Spain.
Sci Total Environ. 2018 Nov 15;642:619-628. doi: 10.1016/j.scitotenv.2018.06.064. Epub 2018 Jun 14.
Climate change can impair ecosystem functions and services in extensive dry forests worldwide. However, attribution of climate change impacts on tree growth and forest productivity is challenging due to multiple inter-annual patterns of climatic variability associated with atmospheric and oceanic circulations. Moreover, growth responses to rising atmospheric CO, namely carbon fertilization, as well as size ontogenetic changes can obscure the climate change signature as well. Here we apply Structural Equation Models (SEM) to investigate the relative role of climate change on tree growth in an extreme Mediterranean environment (i.e., extreme in terms of the combination of sandy-unconsolidated soils and climatic aridity). Specifically, we analyzed potential direct and indirect pathways by which different sources of climatic variability (i.e. warming and precipitation trends, the North Atlantic Oscillation, [NAO]; the Mediterranean Oscillation, [MOI]; the Atlantic Mediterranean Oscillation, [AMO]) affect aridity through their control on local climate (in terms of mean annual temperature and total annual precipitation), and subsequently tree productivity, in terms of basal area increments (BAI). Our results support the predominant role of Diameter at Breast Height (DHB) as the main growth driver. In terms of climate, NAO and AMO are the most important drivers of tree growth through their control of aridity (via effects of precipitation and temperature, respectively). Furthermore and contrary to current expectations, our findings also support a net positive role of climate warming on growth over the last 50 years and suggest that impacts of climate warming should be evaluated considering multi-annual and multi-decadal periods of local climate defined by atmospheric and oceanic circulation in the North Atlantic.
气候变化会损害全球广大干旱森林的生态系统功能和服务。然而,由于与大气和海洋环流相关的多种多年际气候变异性模式,气候变化对树木生长和森林生产力的影响归因具有挑战性。此外,大气 CO 的增长响应,即碳施肥,以及大小个体发育变化,也可能掩盖气候变化的特征。在这里,我们应用结构方程模型 (SEM) 来研究气候变化对极端地中海环境中树木生长的相对作用(即,就沙质不固结土壤和气候干旱的组合而言是极端的)。具体而言,我们分析了不同气候变异性源(即变暖趋势和降水趋势、北大西洋涛动、[NAO];地中海涛动、[MOI];大西洋-地中海涛动、[AMO])通过其对局部气候(以年平均温度和总年降水量表示)的控制,以及随后通过其对树木生产力(以基面积增量表示)的控制,对干旱的潜在直接和间接途径。我们的结果支持胸径(DHB)作为主要生长驱动因素的主导作用。就气候而言,NAO 和 AMO 通过控制干旱(分别通过降水和温度的影响)成为树木生长的最重要驱动因素。此外,与当前的预期相反,我们的研究结果还支持过去 50 年来气候变暖对生长的净积极作用,并表明在评估气候变暖的影响时,应考虑到北大西洋大气和海洋环流定义的多年和数十年的局部气候。
