Differential response of soil characteristics and extracellular enzyme activities along an altitude gradient in a subtropical forest ecosystem

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The differential response of soil characteristics and extracellular enzyme activities along an altitude gradient in a subtropical forest ecosystem highlights the complex interactions between climatic conditions, microbial activity, and soil properties. As altitude increases, changes in temperature, moisture, and vegetation composition significantly influence soil pH, organic carbon, nitrogen content, and microbial biomass. These shifts are closely linked to variations in extracellular enzyme activities responsible for nutrient cycling, such as β-glucosidase, urease, and phosphatase. The study underscores the role of altitude as a key ecological factor regulating soil biochemical processes and microbial functioning, which is essential for understanding ecosystem dynamics and predicting responses to climate change in mountainous regions.

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#SoilScience #AltitudeGradient #SubtropicalForest #SoilEnzymes #ExtracellularEnzymes #SoilEcology #MicrobialActivity #ClimateChangeImpact #SoilBiogeochemistry #ForestEcosystems #EnvironmentalScience #SoilHealth #EcosystemFunction #SoilMicrobiology #NutrientCycling




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