Historic Land Use Modifies Impacts of Climate and Isolation in Rear Edge European Beech (Fagus sylvatica L.) Populations

• Published in: Global change biology Vol. 30; no. 11; pp. e17563 - n/a
• Main Authors: Rhoades, Jazz, Vilà‐Cabrera, Albert, Ruiz‐Benito, Paloma, Bullock, James M., Jump, Alistair S., Chapman, Daniel
• Format: Journal Article
• Language: English
• Published: England Blackwell Publishing Ltd 01.11.2024
• Subjects: adults; biogeography; carbon; climate; Climate Change; Conservation of Natural Resources; Demographics; Demography; Environmental factors; Fagus - growth & development; Fagus sylvatica; Fagus sylvatica subsp. sylvatica; forest ecology; forest inventory; Forest management; Forestry; Forests; Human performance; humans; Iberian Peninsula; Land use; marginality; National Forest Inventory; Population; Population Dynamics; Population studies; Population viability; Populations; probability; range shifts; Recruitment; Spain; species; Transition zone; tree growth; trees; Trees - growth & development; Spain; Iberian Peninsula; land use; range shifts; biogeography; demography; marginality; National Forest Inventory; forest ecology; climate change
• ISSN: 1354-1013; 1365-2486; 1365-2486
• DOI: 10.1111/gcb.17563

ABSTRACT Legacies of human land use have the potential to impact demographic responses to climate. However, few studies have investigated the interactive effects of land use legacies and climate change on tree demography. The demographic performance of rear edge populations in particular is an important determinant of a species' long‐term persistence. In this study, we investigated whether human land use legacies affect demographic responses to climate and population isolation in rear edge European beech populations (Fagus sylvatica L.) at the temperate‐Mediterranean transition zone in the NE Iberian Peninsula. We utilised data from the Spanish Forest Inventory and generalised linear mixed models to compare the potential interactions across four different demographic rates (tree growth, survival probability, new adult recruitment and sapling recruitment). We found that the demographic rates were affected by the combination of land use legacies, climate and population isolation in different ways, which could potentially lead to complex shifts in future population dynamics under climate change. We identified that intense historic management either magnified negative relationships between tree demography and climate or population isolation, or reduced demographic performance in favourable climates to levels observed in unfavourable climates. Through either form of interaction, we found that intense historic forest management had a negative impact on tree demography, which has the potential to compromise future carbon stocks and long‐term population viability. Overall, we show that disentangling human and environmental factors can enable us to better understand heterogeneous demographic performance across the rear edge of species distributions. Past land use may alter how forests respond to climate change or geographic isolation. In our study, we investigated how previous land use may alter the impacts of climate and isolation on growth, survival and recruitment of European beech trees in Spain. We found that intense past forest management negatively impacted tree populations by either worsening climate effects, or reducing performance in favourable conditions to levels seen in unfavourable conditions.