Resilience of soil seed banks to site degradation in intermittently flooded riverine woodlands |
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Authors: | David J. Eldridge Ian D. Lunt |
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Affiliation: | 1. Department of Environment, Climate Change and Water, c/‐ Ecology and Evolution Research Centre, School of Biological, Earth and Environmental Sciences, University of NSW, Sydney, NSW 2052, Australia;2. Institute for Land, Water and Society, Charles Sturt University, PO Box 789 Albury, NSW 2640, Australia ILunt@csu.edu.au |
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Abstract: | Questions: (1) What is the recovery potential of soil seed banks of intact, average and degraded floodplain woodlands? (2) Will soil seed banks of different functional groups (native and exotic, dryland and wetland) display contrasting responses to site degradation? Location: Semi‐arid, seasonally flooded woodland of eastern Australia. Methods: Diversity, abundance and composition of soil seed banks were assessed using a glasshouse study. Surface soil samples were taken from a total of nine sites with three levels of degradation (intact, average, degraded) from three microsites (sub‐canopy, canopy edge, open). Results: A total of 26 662 individuals of 82 species germinated. Seed abundance increased tenfold from intact to degraded sites, but there was no effect on richness. Species composition of all functional groups varied significantly among degradation states. Seeds of native wetland and exotic dryland species were more abundant in degraded than in intact sites. However, the abundance of native dryland germinants did not differ among degradation classes and no seeds of exotic wetland species were observed. Richness of exotic dryland species was significantly higher in degraded sites. Conclusions: Increasing disturbance promoted seed banks of exotic but not native dryland species and native but not exotic wetland species. Unexpectedly, disturbance promoted the abundance of native seeds more than exotics, although this was driven by a single species. Our results suggest that the dryland phase of the floodplain community is more resilient to degradation than predicted. |
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Keywords: | Ecosystem resilience Floodplain vegetation Germinable seed Invasive plants Wetlands |
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