Influence of edaphic factors on plant distribution and diversity in the arid area of Xinjiang, Northwest China

The influence of edaphic factors on plant distribution is essential to community ecology and important for vegetation restoration and management in arid ecosystems. In this study, desert plant distribution and diversity as well as soil water, salinity, and nutrients were measured in the Ebinur Lake...

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Bibliographic Details
Published in:Arid land research and management 2018-01, Vol.32 (1), p.38-56
Main Authors: Zhang, Xue-Ni, Yang, Xiao-Dong, Li, Yan, He, Xue-Min, Lv, Guang-Hui, Yang, Jian-Jun
Format: Article
Language:English
Subjects:
Additives
Arid regions
Biodiversity
Desert environments
Desert plant
Desert plants
Deserts
Distance
Distribution
distribution pattern
Drought
Ecosystem management
Ecosystems
Electrical conductivity
Electrical resistivity
generalized additive models
Hydrogen ions
Lakes
Mineral nutrients
Moisture content
Nitrogen
Nutrients
Organic carbon
Organic soils
pH effects
Phosphorus
Plant diversity
Plants (botany)
Restoration
Rivers
Saline soils
Soil
Soil chemistry
soil environment
Soil pH
Soil remediation
Soil water
Species diversity
Strategic management
Sulfur
Sulphur
Variation
Water content
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Summary:The influence of edaphic factors on plant distribution is essential to community ecology and important for vegetation restoration and management in arid ecosystems. In this study, desert plant distribution and diversity as well as soil water, salinity, and nutrients were measured in the Ebinur Lake Wetland Nature Reserve (ELWNR) in arid Northwest China. We determined relationships between plant distribution and soil factors along a transect with increasing distance from the river and created optimal models using soil factors to explain variations in plant diversity. In general, soil factors decreased with increasing distance from the river. Soil volumetric water content (SVWC), electrical conductivity (EC), pH, nitrogen (N), phosphorus (P), and sulfur (S) were closely related to plant distribution. According to canonical correspondence analysis, plants along the transect were divided into three groups: saline-alkaline tolerant, drought tolerant, and high P-demanding. SVWC, pH, soil organic carbon (C), N, P, and S account for 93.8% of the variations in plant diversity in the ELWNR. Compared with other soil factors, S explained the largest percentage of variations in diversity when single soil variables were considered in generalized additive models (R 2  = 38.9%). Our results suggest increases in soil pH, P, N, and S would improve plant diversity significantly. We found differences among species groups in preference for habitat, and N and S content had a significant positive effect of on plant diversity, providing a scientific reference for plant restoration and saline soil remediation in desert ecosystems.
ISSN:1532-4982
1532-4990
DOI:10.1080/15324982.2017.1376004