Tropical Rainforest Restoration Plantations Are Slow to Restore the Soil Biological and Organic Carbon Characteristics of Old Growth Rainforest
Autor: | Tim E. Smith, D. E. Allen, Susanne Schmidt, Richard Brackin, Luke P. Shoo, Tom Lewis, Mark T. L. Bonner |
---|---|
Rok vydání: | 2019 |
Předmět: |
0301 basic medicine
Conservation of Natural Resources Rainforest 030106 microbiology Soil Science Biology Carbon Cycle Microbial ecology Soil 03 medical and health sciences Microbial function and composition Land use change Restoration ecology Soil Microbiology Ecology Evolution Behavior and Systematics Tropical Climate geography geography.geographical_feature_category Ecology Agroforestry Forest Science Mixed-species plantations Reforestation Environmental impact of agriculture Soil carbon Soil fungi and bacteria Old-growth forest 030104 developmental biology Soil water Soil carbon sequestration Queensland Tropical rainforest |
Zdroj: | Microbial Ecology |
ISSN: | 1432-184X 0095-3628 |
DOI: | 10.1007/s00248-019-01414-7 |
Popis: | Widespread and continuing losses of tropical old-growth forests imperil global biodiversity and alter global carbon (C) cycling. Soil organic carbon (SOC) typically declines with land use change from old-growth forest, but the underlying mechanisms are poorly understood. Ecological restoration plantations offer an established means of restoring aboveground biomass, structure and diversity of forests, but their capacity to recover the soil microbial community and SOC is unknown due to limited empirical data and consensus on the mechanisms of SOC formation. Here, we examine soil microbial community response and SOC in tropical rainforest restoration plantings, comparing them with the original old-growth forest and the previous land use (pasture). Two decades post-reforestation, we found a statistically significant but small increase in SOC in the fast-turnover particulate C fraction. Although the δ13C signature of the more stable humic organic C (HOC) fraction indicated a significant compositional turnover in reforested soils, from C4 pasture-derived C to C3 forest-derived C, this did not translate to HOC gains compared with the pasture baseline. Matched old-growth rainforest soils had significantly higher concentrations of HOC than pasture and reforested soils, and soil microbial enzyme efficiency and the ratio of gram-positive to gram-negative bacteria followed the same pattern. Restoration plantings had unique soil microbial composition and function, distinct from baseline pasture but not converging on target old growth rainforest within the examined timeframe. Our results suggest that tropical reforestation efforts could benefit from management interventions beyond re-establishing tree cover to realize the ambition of early recovery of soil microbial communities and stable SOC. Electronic supplementary material The online version of this article (10.1007/s00248-019-01414-7) contains supplementary material, which is available to authorized users. |
Databáze: | OpenAIRE |
Externí odkaz: |