Organic matter controls of soil water retention in an alpine grassland and its significance for hydrological processes

•SOM rather than soil particle size controls soil water retention in alpine soils.•Two mechanisms of SOM functioning against soil water retention were differentiated.•Pedogenic A horizon is critical in maintaining the alpine ecosystem.•Soil hydrological functions were discussed from multi-perspectiv...

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Bibliographic Details
Published in:Journal of hydrology (Amsterdam) 2014-11, Vol.519, p.3086-3093
Main Authors: Yang, Fei, Zhang, Gan-Lin, Yang, Jin-Ling, Li, De-Cheng, Zhao, Yu-Guo, Liu, Feng, Yang, Ren-Min, Yang, Fan
Format: Article
Language:English
Subjects:
Alpine grassland
Control equipment
Earth sciences
Earth, ocean, space
Exact sciences and technology
Freshwater
Grasslands
Heihe River
Horizon
Hydrological processes
Hydrology
Hydrology. Hydrogeology
Mountains
Pedo-transfer functions
Rivers
Soil (material)
Soil organic matter
Soil water retention
Watersheds
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Summary:•SOM rather than soil particle size controls soil water retention in alpine soils.•Two mechanisms of SOM functioning against soil water retention were differentiated.•Pedogenic A horizon is critical in maintaining the alpine ecosystem.•Soil hydrological functions were discussed from multi-perspectives. Soil water retention influences many soil properties and soil hydrological processes. The alpine meadows and steppes of the Qilian Mountains on the northeast border of the Qinghai-Tibetan Plateau form the source area of the Heihe River, the second largest inland river in China. The soils of this area therefore have a large effect on water movement and storage of the entire watershed. In order to understand the controlling factors of soil water retention and how they affect regional eco-hydrological processes in an alpine grassland, thirty-five pedogenic horizons in fourteen soil profiles along two facing hillslopes in typical watersheds of this area were selected for study. Results show that the extensively-accumulated soil organic matter plays a dominant role in controlling soil water retention in this alpine environment. We distinguished two mechanisms of this control. First, at high matric potentials soil organic matter affected soil water retention mainly through altering soil structural parameters and thereby soil bulk density. Second, at low matric potentials the water adsorbing capacity of soil organic matter directly affected water retention. To investigate the hydrological functions of soils at larger scales, soil water retention was compared by three generalized pedogenic horizons. Among these soil horizons, the mattic A horizon, a diagnostic surface horizon of Chinese Soil Taxonomy defined specially for alpine meadow soils, had the greatest soil water retention over the entire range of measured matric potentials. Hillslopes with soils having these horizons are expected to have low surface runoff. This study promotes the understanding of the critical role of alpine soils, especially the vegetated surface soils in controlling the eco-hydrological processes in source regions of the Heihe River watershed.
ISSN:0022-1694
1879-2707
DOI:10.1016/j.jhydrol.2014.10.054