Abstract
Determining mechanisms of plant establishment in ecological communities can be particularly difficult in disturbance-dominated ecosystems. Longleaf pine (Pinus palustris Mill.) and its associated plant community exemplify systems that evolved with disturbances, where frequent, widespread fires alter the population dynamics of longleaf pine within distinct life stages. We identified the primary biotic and environmental conditions that influence the survival of longleaf pine in this disturbance-dominated ecosystem. We combined data from recruitment surveys, tree censuses, dense lidar point clouds, and a forest-wide prescribed fire to examine the response of longleaf pine individuals to fire and biotic neighborhoods. We found that fire temperatures increased with increasing longleaf pine neighborhood basal area and decreased with higher oak densities. There was considerable variation in longleaf pine survival across life stages, with lowest survival probabilities occurring during the bolt stage and not in the earlier, more fire-resistant grass stage. Survival of grass-stage, bolt-stage, and sapling longleaf pines was negatively associated with basal area of neighboring longleaf pine and positively related to neighboring heterospecific tree density, primarily oaks (Quercus spp.). Our findings highlight the vulnerability of longleaf pine across life stages, which suggests optimal fire management strategies for controlling longleaf pine density, and—more broadly—emphasize the importance of fire in mediating species interactions.
Highlights
Publisher’s Note: MDPI stays neutralDetecting and quantifying ecological interactions in disturbance-prone systems is challenging because the strength and direction of interactions might shift during periods with and without disturbance [1,2]
We observed higher survival probabilities for grass-stage individuals compared to bolt-stage longleaf pines in this large area research plot
Longleaf pines in the bolt stage, an interval of prolific vertical growth, exhibit lower survival, likely because unprotected apical buds are susceptible to fire and the bark has not thickened
Summary
Publisher’s Note: MDPI stays neutralDetecting and quantifying ecological interactions in disturbance-prone systems is challenging because the strength and direction of interactions might shift during periods with and without disturbance [1,2]. The importance, magnitude, and direction of interactions can vary in response to disturbance intensity and frequency [4]. Indirect interactions may arise during disturbance and stress [5], creating complex spatial and temporal dynamics that influence community structure. The sandhill longleaf pine (Pinus palustris Mill.) forests and savannas of the southeastern United States are an ecosystem shaped by disturbances that mediate community interactions. Frequent fires drive forest structure and ecosystem dynamics through processes regulated by the dominant canopy species, primarily longleaf pine [7,8]. Low-intensity fires are spread by highly flammable longleaf pine needles [9,10,11,12]
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