Abstract
AbstractAndosol soils formed in volcanic ash provide key hydrological services in montane environments. To unravel the subsurface water transport and tracer mixing in these soils we conducted a detailed characterization of soil properties and analyzed a 3‐year data set of sub‐hourly hydrometric and weekly stable isotope data collected at three locations along a steep hillslope. A weakly developed (52–61 cm depth), highly organic andic (Ah) horizon overlaying a mineral (C) horizon was identified, both showing relatively similar properties and subsurface flow dynamics along the hillslope. Soil moisture observations in the Ah horizon showed a fast responding (few hours) “rooted” layer to a depth of 15 cm, overlying a “perched” layer that remained near saturated year‐round. The formation of the latter results from the high organic matter (33–42%) and clay (29–31%) content of the Ah horizon and an abrupt hydraulic conductivity reduction in this layer with respect to the rooted layer above. Isotopic signatures revealed that water resides within this soil horizon for short periods, both at the rooted (2 weeks) and perched (4 weeks) layer. A fast soil moisture reaction during rainfall events was also observed in the C horizon, with response times similar to those in the rooted layer. These results indicate that despite the perched layer, which helps sustain the water storage of the soil, a fast vertical mobilization of water through the entire soil profile occurs during rainfall events. The latter being the result of the fast transmissivity of hydraulic potentials through the porous matrix of the Andosols, as evidenced by the exponential shape of the water retention curves of the subsequent horizons. These findings demonstrate that the hydrological behavior of volcanic ash soils resembles that of a “layered sponge,” in which vertical flow paths dominate.
Highlights
Hillslope soils in mountainous environments are essential providers of hydrological services
Despite the importance of hillslope soils in the provisioning of hydrological services, fundamental knowledge about how their properties influence water transport and mixing in the subsurface is lacking (Fan et al, 2019). Filling this knowledge gap is of particular importance in understudied hydrological systems, such as those in which subsurface flow paths are influenced by the presence of soils of volcanic ash origin
Soil water isotopes (SWIs) in Andosols have been used to investigate runoff generation (Mosquera et al, 2016; MuñozVillers & McDonnell, 2012) and water storage (Lazo et al, 2019) in catchments, their application in combination with hydrometric observations and detailed characterization of soil properties is still inexistent. This situation hinders our ability to disentangle flow paths and mixing processes in hillslopes dominated by volcanic ash soils. To fill this knowledge gap, we present a unique data set of soil properties in combination with hydrometric and water isotope measurements in precipitation and soil water collected in an experimental hillslope transect underlain by volcanic ash soils (Andosols)
Summary
Hillslope soils in mountainous environments are essential providers of hydrological services. Soil water isotopes (SWIs) in Andosols have been used to investigate runoff generation (Mosquera et al, 2016; MuñozVillers & McDonnell, 2012) and water storage (Lazo et al, 2019) in catchments, their application in combination with hydrometric observations and detailed characterization of soil properties is still inexistent This situation hinders our ability to disentangle flow paths and mixing processes in hillslopes dominated by volcanic ash soils. Given the highly organic nature of the shallow horizon of the hillslope soils, their moisture release curves were determined from direct soil moisture content and matric potential measurements (Vereecken et al, 2008) using time domain reflectometers (Campbell Scientific CS616) and tensiometers (UMS T8), respectively For this purpose, we took three randomly selected undisturbed soil cores (Ø = 40 cm, h = 32 cm) located in a 5 m × 5 m area around each of the sampling sites along the hillslope to capture the spatial variability of the moisture release characteristic. Further details about the modeling procedure can be found in Mosquera, Segura, et al (2016)
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