Soil–vegetation–water interactions controlling solute flow and chemical weathering in volcanic ash soils of the high Andes

Vegetation plays a key role in the hydrological and biogeochemical cycles. It can influence soil water fluxes and transport, which are critical for chemical weathering and soil development. In this study, we investigated soil water balance and solute fluxes in two soil profiles with different vegeta...

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Bibliographic Details
Published in:Hydrology and earth system sciences 2023-04, Vol.27 (7), p.1507-1529
Main Authors: Páez-Bimos, Sebastián, Molina, Armando, Calispa, Marlon, Delmelle, Pierre, Lahuatte, Braulio, Villacís, Marcos, Muñoz, Teresa, Vanacker, Veerle
Format: Article
Language:English
Subjects:
Aluminum
Analysis
Bicarbonates
Biogeochemical cycle
Biogeochemical cycles
Biogeochemistry
Chemical weathering
Cushions
Depth
Dissolved organic carbon
Evapotranspiration
Fluxes
Grasses
Horizon
Hydraulic conductivity
Hydraulics
Hydrogeology
Hydrologic cycle
Hydrology
Iron
Metals
Moisture content
Nutrient uptake
Nutrients
Organic carbon
Plants
Plants (botany)
Silica
Soil chemistry
Soil hydrology
Soil investigations
Soil moisture
Soil profiles
Soil properties
Soil water
Soils
Solutes
Topography
Uptake
Vegetation
Volcanic ash
Volcanic soils
Water balance
Water balance (Hydrology)
Water content
Weathering
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Summary:Vegetation plays a key role in the hydrological and biogeochemical cycles. It can influence soil water fluxes and transport, which are critical for chemical weathering and soil development. In this study, we investigated soil water balance and solute fluxes in two soil profiles with different vegetation types (cushion-forming plants vs. tussock grasses) in the high Ecuadorian Andes by measuring soil water content, flux, and solute concentrations and by modeling soil hydrology. We also analyzed the role of soil water balance in soil chemical weathering. The influence of vegetation on soil water balance and solute fluxes is restricted to the A horizon. Evapotranspiration is 1.7 times higher and deep drainage 3 times lower under cushion-forming plants than under tussock grass. Likewise, cushions transmit about 2-fold less water from the A to lower horizons. This is attributed to the higher soil water retention and saturated hydraulic conductivity associated with a shallower and coarser root system. Under cushion-forming plants, dissolved organic carbon (DOC) and metals (Al, Fe) are mobilized in the A horizon. Solute fluxes that can be related to plant nutrient uptake (Mg, Ca, K) decline with depth, as expected from biocycling of plant nutrients. Dissolved silica and bicarbonate are minimally influenced by vegetation and represent the largest contributions of solute fluxes. Soil chemical weathering is higher and constant with depth below tussock grasses but lower and declining with depth under cushion-forming plants. This difference in soil weathering is attributed mainly to the water fluxes. Our findings reveal that vegetation can modify soil properties in the uppermost horizon, altering the water balance, solute fluxes, and chemical weathering throughout the soil profile.
ISSN:1607-7938
1027-5606
1607-7938
DOI:10.5194/hess-27-1507-2023