Coupling effects of soil and vegetation from an ecosystem service perspective

Abstract

Soil provides diverse ecosystem services (ESs) to people, yet anthropogenic activities result in the degradation and loss of soil ESs. Therefore, there is an urgent need to take effective measures to protect and manage soils for sustainable development. However, the differences in ESs across soil types are not well understood, and the coupling effects of soil and vegetation on ESs at different altitudes remain unclear. In this study, the composition of soil and vegetation types under different altitude gradients were analyzed and the differences/similarities of ESs (in terms of water yield, carbon storage, and soil conservation) among different soil types were identified. Following this, the optimal soil and vegetation combinations under different altitude gradients were determined from an ES perspective. The results revealed that soil types and ESs differed markedly at each altitude gradient. ESs in the high-altitude zone were significantly higher than those in the low-altitude zone (p < 0.01). There was an obvious difference in the ES supply capacity of soil types, with brown earths and dark felty soils exhibiting higher ESs compared to purplish soils, paddy soils, red earths, and yellow earths. The felty soils and alpine steppe combination, brown coniferous forest soils and evergreen needleleaf forest combination, and brown earths and evergreen broadleaf forest combination provided the highest water yield, carbon storage, and soil conservation, respectively. Vegetation can promote or inhibitat soil ESs, depending on the vegetation and soil types. Based on the results, detailed soil and vegetation management measures were proposed for different altitudes. Dark-brown earths and dark felty soils were identified as priority soil types for protection. This study provides an important reference for soil management and landscape restoration.