Factors influencing soil carbon stocks in secondary subtropical forests

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Soil carbon stocks in secondary subtropical forests are shaped by a complex interaction of ecological, environmental, and management factors. Vegetation type and species composition play a key role, as diverse plant communities contribute varying amounts and qualities of litter that influence organic matter accumulation. Soil properties such as texture, pH, and nutrient availability also affect carbon stabilization and microbial activity. Climate factors, including temperature and rainfall, regulate decomposition rates and carbon cycling. Forest age and successional stage determine the extent of carbon recovery, with older forests typically storing more carbon than younger regenerating stands. Human activities, such as past land use, disturbance intensity, and forest management practices, further influence carbon sequestration potential. Together, these factors shape the long-term capacity of secondary subtropical forests to serve as vital carbon sinks, contributing significantly to climate change mitigation.

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#SoilCarbon #SubtropicalForests #CarbonSequestration #ForestEcology #SecondaryForests #ClimateChangeMitigation #SoilHealth #CarbonStocks #EcosystemServices #ForestRestoration #SoilBiology #CarbonCycle #SustainableForestry #ForestCarbon #SoilScience




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