Radial growth of subarctic tree and shrub species: relationships with climate and association with the greening of the forest-tundra ecotone of subarctic Québec, Canada

IF 2.7 3区地球科学 Q2 ECOLOGY

Arctic Science Pub Date : 2023-10-17 DOI:10.1139/as-2023-0030

Julie-Pascale Labrecque-Foy, Anna Gaspard, Martin Simard, Stephane Boudreau

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引用次数: 0

Abstract

Climate change has resulted in a widespread increase in primary productivity in northern regions. This “greening” can alter terrestrial ecosystems dynamics and trigger positive climate feedbacks, but often exhibits spatial heterogeneity. Few studies have focused on the differential responses of plant functional groups to warming as a potential driver of heterogeneity in greening rates. Our objective was to determine if climate-growth relationships are species-specific, and if they can explain the heterogeneity of the subarctic greening rates. We compared climate-growth relationships and associations to NDVI of the dominant tree (Picea mariana) and shrub (Betula glandulosa) species at two locations in the forest-tundra ecotone in Nunavik (Québec, Canada). Correlation coefficients of the climate-growth relationship varied between species and locations, being higher for P. mariana and at the northernmost location. The lower association between NDVI and P. mariana radial growth at the northernmost location appeared to be compensated by a stronger association between NDVI and B. glandulosa radial growth. Our results show that response to climate varies spatially and between species, both of which could potentially be used to explain the heterogeneity of subarctic greening rates. This improved understanding of the species-specific response to climate change will help predict forthcoming changes in primary productivity and their potential positive feedback on climate change.

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亚北极乔木和灌木物种的径向生长:与气候的关系和与森林-苔原过渡带绿化的关联

气候变化导致北方地区初级生产力普遍提高。这种“绿化”可以改变陆地生态系统动态并引发积极的气候反馈，但往往表现出空间异质性。很少有研究关注植物功能群对变暖的差异反应作为绿化率异质性的潜在驱动因素。我们的目标是确定气候增长关系是否具有物种特异性，以及它们是否可以解释亚北极绿化率的异质性。研究人员比较了加拿大努纳维克(quamesbec, Canada)森林-冻土带过渡带两个地点的优势乔木(Picea mariana)和灌木(Betula glandulosa)物种的气候-生长关系及其与NDVI的关联。气候-生长关系的相关系数在不同的物种和地点之间存在差异，在最北的地点，马里亚纳草的相关系数较高。在最北端，NDVI与mariana径向生长的相关性较低，但NDVI与B. glandullosa径向生长的相关性较强。我们的研究结果表明，对气候的响应在空间和物种之间存在差异，这两者都可能被用来解释亚北极绿化速率的异质性。这种对物种对气候变化的特异性响应的更好理解将有助于预测初级生产力即将发生的变化及其对气候变化的潜在正反馈。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Arctic Science Agricultural and Biological Sciences-General Agricultural and Biological Sciences

CiteScore

5.00

自引率

12.10%

发文量

期刊介绍： Arctic Science is an interdisciplinary journal that publishes original peer-reviewed research from all areas of natural science and applied science & engineering related to northern Polar Regions. The focus on basic and applied science includes the traditional knowledge and observations of the indigenous peoples of the region as well as cutting-edge developments in biological, chemical, physical and engineering science in all northern environments. Reports on interdisciplinary research are encouraged. Special issues and sections dealing with important issues in northern polar science are also considered.