The eastern Hengduan Mountains are located in the transition zone between the Qinghai-Tibet Plateau and the Sichuan Basin and are important for global biodiversity and water conservation in China. However, their landscape pattern vulnerability index (LVI) and its influencing factors have not been systematically studied. Therefore, the spatial distribution patterns, LVI, and the landscape artificial disturbance intensity (LHAI) of Ganzi Prefecture were analyzed using ArcGIS software based on landscape data and Digital Elevation Model (DEM) digital elevation data. Then, the LVI response to LHAI and elevation was discussed. The results showed that Ganzi Prefecture was dominated by low- and middle-LVI areas, together accounting for 56.45% of the total area. LVI values were highest in the northern regions, followed by the southern and eastern regions. Batang and Derong counties had the highest LVI values. Most areas in Ganzi Prefecture had very low- or low-LHAI values, accounting for 81.48% of the total area, whereas high-LHAI areas accounted for 2.32% of the total area. Both the LVI and LHAI of Ganzi Prefecture had clustered distributions. Spearman analysis indicated that when elevation exceeded 4500 m, it was the most important factor affecting LVI and LHAI. In the range of 4500–5400 m, the relationship between elevation and LVI shifted from a weak positive correlation to a negative correlation, whereas LHAI was positively correlated with elevation. In addition, LVI also responded significantly to LHAI. However, the relationship kept changing as elevation increased. Hence, the ecological vulnerability of high elevation areas above 4500 m deserves greater attention. In addition, pasture areas in the upstream reaches of the Yalong River in the northern region, the coastal area in the downstream reaches of the Jinsha River in the southern region, and the eastern mining area, should be prioritized for protection and restoration. This research provides a basis for appropriate environmental planning mechanisms and policy protections at the landscape level.
Obvious changes of hydrologic regimes occurred in wetland around the
world, and it also were expected to arise in the following 100 years.
This study examined the response of soil microbial functional structure
and metabolic potential to early dry season (EDS) of Dongting Lake
wetland, China. We measured the soil properties, microbial functional
structure of samples E40, E20 and E0 (dry season arrived early by 40, 20
and 0 days, respectively). The results showed that the EDS caused the
changes of functional structure: the functional genes of E40 had
significantly higher abundance and diversity than those of E0, but no
significant difference was found between those of E20 and E0. Functional
genes associated with matter cycling and organic contaminant degradation
(OCD) also were changed. It could cause the increase of the degradation
of pesticides related compound of E20 and matter cycling and OCD of E40
(except no change in the phosphorus oxidation and the degradation of
polycyclic aromatics and terpenoid).
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