Influence of roots on soil preferential paths for infiltration in typical vegetation of the Loess Plateau

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The influence of plant roots on soil preferential paths for infiltration plays a critical role in shaping water movement in the Loess Plateau, a region known for its fragile ecology and deep loess deposits. Vegetation typical of this area, such as Robinia pseudoacacia, Caragana korshinskii, and various native grasses, contributes to the development of root channels that enhance preferential flow pathways. These root-induced macropores allow rainwater to bypass the compacted soil matrix, improving water infiltration efficiency and reducing surface runoff and erosion. Over time, these biological structures not only increase soil moisture retention but also promote soil stability and ecosystem resilience. Understanding the dynamic interaction between root systems and infiltration pathways is essential for designing effective soil and water conservation strategies in semi-arid environments like the Loess Plateau.


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#LoessPlateau #SoilInfiltration #RootEcology #PreferentialFlow #SoilWaterDynamics #VegetationImpact #ErosionControl #WaterConservation #SoilStructure #EcoHydrology #LandRestoration #Macropores #SustainableLandUse #SemiAridEcosystems #SoilHealth





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